JP6115248B2 - Parking assistance device - Google Patents

Description

  The present invention relates to a parking assistance device that supports a process of parking a host vehicle in a target parking space.

  Regarding this type of device, by operating the arrow button switch displayed on the touch panel display, the position of the target parking frame displayed on the display is moved, and the process of parking the vehicle at the location indicated by the target parking frame is supported. An apparatus is known (Patent Document 1).

JP 2007-118878 A

  However, in the conventional technology, the driver is required to operate another switch while visually observing the position of the target parking frame shown on the display, so that the position adjustment is difficult and the operability is low. There's a problem.

  The problem to be solved by the present invention is to improve the operability related to the position adjustment of the target parking space where the host vehicle is parked.

The present invention presents a parking space setting frame superimposed on a bird's-eye view image of the host vehicle and designates a first input point that is a position on the parking space setting frame or in the parking space setting frame; Receiving a second input for designating a second input point at a position different from the input point, and centering on the first input point in a direction corresponding to the direction of rotation of the second input point rotating relative to the first input point The above-described problem is solved by rotating the parking space setting frame to adjust the position.

  According to the present invention, the position of the parking space setting frame can be changed in accordance with the change in the relative position specified by the first input and the second input, so that the driver is presented in the overhead image. While confirming the position of the host vehicle, the position of the parking space and the position of the parking space setting frame with one image information, the position of the parking space setting frame in the specified direction (in a common coordinate system) on the image information Can be adjusted. As a result, the operability of position adjustment when setting the target parking space can be improved.

It is a block diagram of the parking assistance system of embodiment which concerns on this invention. It is a flowchart figure which shows the control procedure of the driving assistance system which concerns on embodiment of this invention. It is a figure which shows an example of the installation position of the vehicle-mounted camera of this embodiment. It is a figure which shows the example of a display of the bird's-eye view image of this embodiment. It is a 1st figure for demonstrating the operation aspect which rotates (autorotates) the parking space setting frame. It is a 2nd figure for demonstrating the operation aspect which rotates (autorotates) the parking space setting frame. It is a 1st figure for demonstrating the operation aspect which rotates (revolves) a parking space setting frame. It is a 2nd figure for demonstrating the operation aspect which rotates (revolves) a parking space setting frame. It is a 1st figure for demonstrating the operation mode which translates a parking space setting frame (transverse direction). It is a 2nd figure for demonstrating the operation mode which moves a parking space setting frame in parallel (horizontal direction). It is a 1st figure for demonstrating the operation aspect which moves a parking space setting frame in parallel (vertical direction). It is a 2nd figure for demonstrating the operation mode which moves a parking space setting frame in parallel (vertical direction). It is a 1st figure for demonstrating the method of rotating a parking space setting frame (self-rotating) and adjusting a position. It is a 2nd figure for demonstrating the method of rotating (autorotating) a parking space setting frame and adjusting a position. It is a 3rd figure for demonstrating the method of rotating and rotating a parking space setting frame and adjusting a position. It is a 1st figure for demonstrating the method of rotating (revolving) a parking space setting frame and adjusting a position. It is a 2nd figure for demonstrating the method of rotating (revolving) a parking space setting frame and adjusting a position. It is a 3rd figure for demonstrating the method of rotating (revolving) a parking space setting frame and adjusting a position. It is the 1st figure for demonstrating the method of moving a parking space setting frame and adjusting a position. It is a 2nd figure for demonstrating the method of rotating (revolving) a parking space setting frame and adjusting a position. It is a 3rd figure for demonstrating the method of rotating (revolving) a parking space setting frame and adjusting a position. It is the 1st figure for explaining an example of parking assistance processing. It is a 2nd figure for demonstrating an example of parking assistance processing.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the present embodiment, a case where the parking support apparatus according to the present invention is applied to a parking support system 1000 mounted on a vehicle will be described as an example.

  FIG. 1 is a block diagram of a parking assistance system 1000 having a parking assistance apparatus 100 according to an embodiment of the present invention. The parking support system 1000 according to the present embodiment supports an operation of moving (parking) the host vehicle in the parking space 200. The parking assistance system 1000 of this embodiment includes a camera 1a to 1d, an image processing device 2, a vehicle controller 30, a drive system 40 of the host vehicle V, a steering device 50 including a steering angle sensor 51, and a vehicle speed sensor 60. With. The parking assistance device 100 of this embodiment includes a control device 10 and an input / output device 20 such as a touch panel display 201 having an input / output function. Each component of the parking support system 1000 shown in FIG. 1 and each in-vehicle device (not shown) are connected by a CAN (Controller Area Network) or other in-vehicle LAN in order to exchange information with each other.

  The parking assist device 100 according to the present embodiment is mounted on the host vehicle V and in a parking mode desired by the driver (parallel parking, parallel parking, diagonal parking, etc.), the target parking set by the driver using the parking space setting frame F2. It is a device that supports an operation of parking the host vehicle V in the space 200.

  The control device 10 of the parking assistance apparatus 100 according to the present embodiment includes a ROM 12 that stores a parking assistance program, and an operation circuit that functions as the parking assistance apparatus 100 according to the present embodiment by executing the program stored in the ROM 12. And a RAM 13 that functions as an accessible storage device.

  The parking assistance program according to the present embodiment is configured to superimpose setting auxiliary information including a parking space setting frame on a bird's-eye view image including an image of the parking space, and to display the instruction on the display 201 to adjust the position of the presented parking space setting frame. This is a program for executing an operation for assisting an operation of parking the host vehicle V in the parking space corresponding to the position of the parking space setting frame. The contents will be described in detail later.

  The control device 10 of the parking assistance device 100 of the present embodiment includes a parking assistance control unit. The parking assist control unit is based on EPS based on shift range information from the AT / CVT control unit, wheel speed information from the ABS control unit, rudder angle information from the rudder angle sensor control unit, engine speed information from the ECM, etc. It calculates and outputs instruction information related to automatic steering to the control unit, instruction information such as warnings to the meter control unit, and the like. The control device 10 can acquire each information acquired by the various sensors 60 via the vehicle controller 30.

  The drive system 40 of the present embodiment is a drive mechanism of the host vehicle V for performing parking support, and parks the host vehicle V in the target parking space 200 by driving based on a control command signal acquired from the parking support apparatus 100. To support the operation. The steering device 50 of the present embodiment is a drive mechanism that moves the host vehicle in the left-right direction. The EPS motor included in the drive system 40 controls the steering amount by driving the power steering mechanism provided in the steering of the steering device 50 based on the control command signal acquired from the parking assist device 100, and sets the host vehicle V to the target parking space. The operation at the time of moving to 200 is supported. In addition, the content and operation | movement technique of parking assistance are not specifically limited, The technique known at the time of application can be applied suitably.

  The control device 10 of the parking assistance device 100 according to the present embodiment realizes a captured image acquisition function, an image generation function, a parking information presentation function, a position adjustment function, a target parking space setting function, and a parking assistance function. The above functions are executed by the cooperation of the software and the hardware described above.

  The parking support system 1000 according to the present embodiment executes a parking support process shown in the flowchart of FIG. The trigger for starting the parking support process is not particularly limited, and it may be a trigger that the start switch of the parking support apparatus 100 is operated, or a trigger that is a predetermined speed (for example, 10 km / h or less). Good.

  Specifically, the control device 10 of the parking assistance device 100 according to the present embodiment acquires captured images captured by the cameras 1a to 1d attached to a plurality of locations of the host vehicle V in step 101, respectively. The cameras 1a to 1d are composed of a CCD camera or the like, and capture an image of a boundary line of the parking space 200 around the host vehicle V and an object existing around the host vehicle V. FIG. 3 is a diagram illustrating an arrangement example of the cameras 1 a to 1 d mounted on the host vehicle V. In the example shown in FIG. 3, the camera 1 a is disposed on the front grill portion of the host vehicle V, the camera 1 d is disposed near the rear bumper, and the cameras 1 b and 1 c are disposed below the left and right door mirrors. The cameras 1a to 1d use wide-angle cameras with a wide viewing angle.

  In step 102, the control device 10 of the parking assistance device 100 causes the image processing device 2 to generate an overhead image. The image processing apparatus 2 determines the surrounding state including the host vehicle V and the parking space 200 in which the host vehicle V is parked based on the acquired plurality of captured images, and a viewpoint P above the host vehicle V (see FIG. 3). A bird's-eye view image as seen from is generated. Image processing performed by the image processing apparatus 2 is, for example, “Masayasu Suzuki, Satoshi Chimino, Teruhisa Takano, Development of a bird's-eye view system, Preprints of the Society of Automotive Engineers of Japan, 116-07 (2007-10), 17- 22. "etc. can be used.

  FIG. 4 is a diagram illustrating an example of a display mode of the generated overhead image 21. It is a figure which shows the example of a display of the bird's-eye view image (top view) 21 around the own vehicle, and the monitoring image | video (normal view) 22 around the own vehicle. As shown in FIG. 4, in the present embodiment, an overhead image (top view) 21 whose viewpoint is converted to the virtual viewpoint P in FIG. 3 is displayed on the left side of the screen of the display 20 and captured by any of the cameras 1 a to 1 d. The monitored image (normal view) 22 is displayed on the right side of the screen. An overhead view image (top view) 21 displayed on the left side of the screen of the input / output device (display) 20 includes an image showing the parking space 200 (a boundary line of the parking space 200). In addition, a host vehicle icon V indicating the position of the host vehicle is displayed at the center of the overhead image (top view) 21. The monitoring images (normal view) can be taken images of different cameras 1a to 1d depending on the operation state of the host vehicle V. In the example shown in FIG. 4, the captured image of the camera 1a is displayed on the front grille portion of the host vehicle V, but when the host vehicle V moves backward, the captured image of the camera 1d disposed near the rear bumper is displayed. May be.

  Returning to FIG. 2, in step 103, parking mode selection information is received. The parking mode of the present embodiment includes at least six modes including a right side or left side parallel parking mode, a right side or left side parallel parking mode, and a right side or left side diagonal parking mode. The driver inputs selection information for selecting any parking mode that matches the positional relationship between the host vehicle V and the parking space 200 in which parking is desired. And the parking assistance apparatus 100 acquires the selection information of the parking mode which selects any one parking mode from the several parking modes including right and left parallel parking and left and right parallel parking. The parking mode may be selected by touching any of the parking modes displayed on the touch panel display 201, or may be selected by a switch operation associated with each parking mode. Note that the selection of the parking mode in step 103 can be performed prior to the acquisition of the captured image (S101) and the generation of the overhead image (S102). It is also possible to configure the control procedure so that the setting auxiliary information in step S104 is presented after step S102, the parking mode is selected in step 103, and then the process proceeds to step S105.

  In step 104, the control device 10 presents the setting auxiliary information F (F2, F3). As shown in FIG. 4, the control device 10 superimposes the setting auxiliary information F on the overhead image 21 and presents it on the input area of the touch panel display 201. The reason why the setting auxiliary information F is presented in the input area is to accept an input of a position adjustment command for the setting auxiliary information F and a command for setting the target parking space by the driver. The auxiliary setting information F of the present embodiment includes a parking space setting frame F2 and an obstacle avoidance frame F3 as necessary.

  In the presented image, the parking space setting frame F2 is displayed at a predetermined position with respect to the host vehicle V. Although not particularly limited, the parking space setting frame F <b> 2 is a rectangular figure corresponding to the shape of the parking space 200. The obstacle avoidance frame F3 is a sign indicating a boundary between a region having a high possibility of contact with an obstacle and a region having a low possibility of contact with the obstacle. The driver performs parking so that the host vehicle V does not come into contact with the obstacle by operating the host vehicle V so that there is no solid object inside the obstacle avoidance frame F3 (the parking space setting frame F2 side). Can do. The obstacle avoidance frame F3 is displayed outside the parking space setting frame F2 and at a predetermined position with respect to the parking space setting frame F2. Although not particularly limited, the obstacle avoidance frame F3 is a bowl-shaped figure in which two lines (rectangles) are substantially orthogonal. The positional relationship of the obstacle avoidance frame F3 with respect to the parking space setting frame F2 and the display mode (size, length, etc.) of the obstacle avoidance frame F3 depend on the size of the host vehicle V, performance characteristics (turning radius), etc. Define as appropriate.

  Although not particularly limited, in the present embodiment, the positional relationship between the parking space setting frame F2 and the obstacle avoidance frame F3 is kept constant and displayed. That is, when the parking space setting frame F2 moves, the obstacle avoidance frame F3 also moves together. On the displayed image information, when the obstacle avoidance frame F3 is moved, the parking space setting frame F2 is moved along with the obstacle avoidance frame F3. In this way, by performing position adjustment while maintaining the positional relationship between the parking space setting frame F2 and the obstacle avoidance frame F3, the driver checks the position of the host vehicle and the position of the parking space setting frame F2. , You can check on the screen the approach and interference with obstacles when parking.

  Although not particularly limited, in the present embodiment, the parking space setting frame F2 is displayed in a predetermined first color (for example, red), and the obstacle avoidance frame F3 is displayed in a second color (for example, blue) different from the first color. indicate. Thereby, the parking space setting frame F2 and the obstacle avoidance frame F3 displayed simultaneously in the position image information can be easily identified.

  The driver performs an operation for setting the target parking space 200 using the presented parking space setting frame F2. The parking space setting frame F2 of this embodiment is displayed at a predetermined position with respect to the host vehicle V, and the position of the parking space setting frame F2 can be changed by moving the host vehicle V. The driver selects the target parking space 200 in which the host vehicle V is parked by superimposing the parking space setting frame F2 on the parking space 200 in which the host vehicle V is desired to be parked. After the driver selects the target parking space 200 at the position of the parking space setting frame F2, if the position of the parking space setting frame F2 is appropriate, the driver operates the decision button or the like to select the parking space 200. The completion is input to the parking assistance device 100. That is, when the stop position of the host vehicle is appropriate and position adjustment is not necessary, step S105 is skipped and the process proceeds to step S106. On the other hand, if the position of the parking space setting frame F2 is not appropriate, the decision button or the like is operated after adjusting the position of the parking space setting frame F2, and the parking support device 100 is informed that the selection of the parking space 200 has been completed. input. If it is necessary to adjust the position before setting the target parking space 200, the process of step S105 is performed.

  Hereinafter, the position adjustment of the parking space setting frame F2 performed before the final setting of the target parking space 200 will be described. In step S <b> 105, the control device 10 of the parking assistance device 100 according to the present embodiment accepts a position adjustment command (position movement command) for the parking space setting frame F <b> 2 displayed superimposed on the overhead image 21. This position adjustment command is input by an input operation of the driver. The control device 10 changes the position of the parking space setting frame F2 according to the position adjustment command.

  Incidentally, in the parking assist device 100 of the present embodiment, in the target parking space setting process that is executed later (step S106), the parking space 200 (corresponding to the position of the parking space setting frame F2 on the overhead view image 21). The parking space 200) existing at the position overlapping the parking space setting frame F2 on the overhead image 21 is recognized as the target parking space 200 where the host vehicle V is parked.

  If the position of the parking space setting frame F2 is deviated from the position of the target parking space 200 (if the parking space setting frame F2 and the target parking space 200 are not accurately overlapped), the movement of the host vehicle during parking is performed. Since the track is not accurately calculated, it becomes difficult to move the host vehicle to the parking space 200 that the driver originally wants to park. The displacement between the parking space setting frame F2 and the target parking space 200 includes a displacement in the oblique direction (rotation direction) and a displacement in the vertical and horizontal directions. The positional deviation in the oblique direction means that the parking space setting frame F2 is inclined with respect to the target parking space 200, and the border line (including the extension line) of the parking space setting frame F2 and the boundary line (extended line) of the target parking space 200 Including) intersect with each other at an angle. This state occurs when the host vehicle does not stop parallel to the arrangement direction of the target parking space 200. Further, the positional deviation in the vertical and horizontal directions is a state in which the parking space setting frame F2 is shifted in the vertical and horizontal directions (xy directions in the drawing) with respect to the target parking space 200. This state occurs when the host vehicle stops before the center of the target parking space 200, stops too far from the center, or stops away from the parking space 200. In any case, if the target parking space 200 is set in a state in which the position remains shifted, the movement trajectory (parking trajectory) of the host vehicle V from the current position of the host vehicle V to the target parking space 200 is changed. It cannot be calculated accurately. That is, it becomes difficult to move the host vehicle to the parking space 200 that the driver originally wants to park.

  However, it is not easy to drive the host vehicle parallel to the parking space 200 every time it is parked and stop the host vehicle so that the reference of the host vehicle V comes to the center of the target parking space 200. In particular, it is not easy for a driver who is unfamiliar with driving or a driver who gets on a vehicle that is different in every driving for car sharing or the like to stop the vehicle at a target position.

  In addition, as in the device described in the prior art document, the vehicle is placed at the location indicated by the parking frame by operating the arrow button switch that is displayed on the touch panel display separately from the image of the parking frame that is the position adjustment target. There is also a method of parking the vehicle, but while viewing the captured image of the actual parking frame shown on the display, the position of the parking frame must be operated with a switch provided separately from this captured image. Fine position adjustment is difficult and operability is still low.

  On the other hand, in this embodiment, the position of the parking space setting frame F2 is set according to the change in the relative position of the second input point with respect to the first input point having a predetermined positional relationship with the parking space setting frame F2. On the bird's-eye view image 21 of the frame F2, adjustment is performed with reference to the common coordinate system, and the positional deviation (direction) and the vertical and horizontal positional deviation between the parking space setting frame F2 and the target parking space 200 are eliminated. That is, in the present embodiment, a first input that specifies a first input point having a predetermined positional relationship with respect to the parking space setting frame F2 and a second input point that is a position different from the first input point are specified. The second input is received, and the position adjustment is performed by changing the position of the parking space setting frame in accordance with the change in the relative position of the second input point with respect to the first input point. Thereby, first, the first input point to be the reference position is specified, and then the relative position of the second input point with respect to the first input point is changed, so that the parking space setting frame F2 is changed according to the change of the relative position. Can be moved.

  Furthermore, in this embodiment, the 1st input which designates the 1st input point which has predetermined | prescribed positional relationship with respect to the parking space setting frame F2, and the 2nd input point which is a position different from a 1st input point are designated. The second input is received, and the parking space setting frame F2 is rotated around the position of the first input point in the direction corresponding to the rotation direction of the second input point that rotates and moves with respect to the first input point. Do. Thereby, first, the first input point as the rotation reference is designated, and then the second input point is rotated relative to the first input point, so that the parking space setting frame F2 is rotated according to the rotational movement. be able to.

  Furthermore, in this embodiment, the parking space setting frame F2 is rotated by arranging the position of the first input point serving as the rotation center on or inside the parking space setting frame F2 that is the position adjustment target. In addition, the parking space setting frame F2 can be revolved by disposing the position of the first input point serving as the rotation center outside the parking space setting frame F2 that is the position adjustment target.

  Hereinafter, regarding the position adjustment method of the parking space setting frame F2, a first position adjustment method by rotating the parking space setting frame F2, a second position adjustment method by revolving the parking space setting frame F2, and parking Each of the third position adjustment methods by translating the space setting frame F2 will be described.

  The first position adjusting method is a method of adjusting the position by rotating the parking space setting frame F2. In this position adjustment method, the parking space setting frame F2 rotates around the first input point having a predetermined positional relationship with the parking space setting frame F2, that is, rotates. This method is particularly useful as a position adjustment method when the host vehicle V cannot be stopped parallel to the parking space 200.

The control device 10 of the present embodiment specifies a first input that designates a first input point set at a predetermined position with respect to the parking space setting frame F2, and a second that designates a second input point other than the first input point. Accept input. And the control apparatus 10 rotates the parking space setting frame F2 with respect to the bird's-eye view image 21 in the direction according to the rotation direction of the 2nd input point rotated and moved with respect to the 1st input point, and performs position adjustment. The first input point in the present embodiment is on the parking space setting frame F2 (on the diagram showing the parking space setting frame F2) or inside the parking space setting frame F2 (inside the diagram showing the parking space setting frame F2). ). The first input point may be provided on the boundary line of the parking space setting frame F2, or may be provided at the center of gravity (center) of the parking space setting frame F2. In the present embodiment, a borderline of the parking space setting frame F2, parked in a point located in the center of the vehicle front (the front bumper side) is defined as a first input point.

  5A and 5B are views for explaining an operation method for adjusting the position of the parking space setting frame F2. In the example shown in FIG. 5A, the first input point Q1 is set at a predetermined position on the boundary line of the parking space setting frame F2, and the second input point Q2A is an input point other than the first input point Q1, and the first input It is set at a position different from the point Q1. As shown in FIG. 5A, the driver designates the first input point Q1 with the thumb, performs the first input, designates the second input point Q2A with the index finger, and designates the index finger with the second input from the second input point Q2A. Move to point Q2B. Then, as shown in FIG. 5B, the parking space setting frame F2 rotates around the first input point Q1 along the rotation direction from the second input point Q2A to Q2B.

  When performing this second input, the driver performs a linear second input point (Q2A and Q2B) from the second input point Q2A to Q2B along an arcuate operation flow line centered on the first input point Q1. The second input operation is performed so as to trace the arc). That is, from the start of the second input to the end of the second input, the finger that indicates the second input point is in contact with the screen of the display 201. Instead of this operation, the driver individually taps one or two or more point-like second input points Q2A and Q2B that exist discretely on an arc-shaped operation flow line centered on the first input point Q1 ( The second input operation may be performed. In this case, between the start of the second input and the end of the second input, the finger indicating the second input point Q2 touches or separates the screen of the display 201.

  When receiving the position adjustment, the control device 10 superimposes the setting auxiliary information F including the parking space setting frame F2 and the obstacle avoidance frame F3 on the overhead image 21 and presents it on the input area of the display 201.

  The control device 10 changes the position of the parking space setting frame F2 based on the driver input information. As shown in FIG. 5B, the control device 10 is centered on the first input point Q1, centered on the first input point Q1 according to the rotation direction from the second input point Q2A to the second input point Q2B, and the background. The parking space setting frame F2 is rotated (autorotated) with respect to the bird's-eye view image 21. FIG. 5B shows a state after the parking space setting frame F2 and the obstacle avoidance frame F3 are rotated (spinned) with respect to the overhead image 21. As shown in FIG. 5B, the parking space setting frame F2 and the obstacle avoidance frame F3 have the same direction as the rotation direction from the second input point Q2A to the second input point Q2B (reverse to the first input point Q1). Rotate clockwise.

  The control device 10 rotates the parking space setting frame F2 with respect to the sketch image 21 with a rotational movement amount corresponding to the rotational movement amount of the second input points Q2A and Q2B that rotate and move with respect to the first input point Q1. The rotation movement amount of the parking space setting frame F2 depends on the rotation amount when moving from the second input point Q2A to Q2B around the first input point Q1 shown in FIG. 5A. Specifically, when the driver touches the second input point Q2A and then moves the finger to the second input point Q2B, the driver responds to the central angle between the second input point Q2A and the second input point Q2B. And rotate the parking space setting frame F2. When the central angle between the second input point Q2A and the second input point Q2B is 10 degrees, the parking space setting frame F2 may be rotated by 10 times, or twice by 20 degrees. It is good or you may rotate by half 5 degrees. This correspondence can be arbitrarily defined in advance. This correspondence can be arbitrarily defined in advance.

  In the present embodiment, the rotation of the parking space setting frame F2 is the rotation about the first input point Q1 set on the parking space setting frame F2, so that the operator (driver) has the rotation direction and the rotation amount. Easy to grasp. In other words, in the position adjustment operation of the parking space setting frame F2, the driver can rotate the second input point in what direction, in which direction, and how much the rotation amount, and how the parking space setting frame F2 is changed. It can be predicted whether it will rotate.

  As shown in the figure, in this embodiment, since the positional relationship between the parking space setting frame F2 and the obstacle avoidance frame F3 is kept constant, the obstacle avoidance frame F3 is also centered on the first input point Q1. The second input points Q2A and Q2B are rotated along the rotation direction according to the rotation amount.

  In this embodiment, the bird's-eye view image 21 including the host vehicle V and the parking space 200 and the parking space setting frame F2 (an obstacle avoidance frame F3 as necessary) arranged at a predetermined position with respect to the host vehicle V are provided. In the image information, the driver specifies the rotation center of the parking space setting frame F2 in the common coordinate system, and the rotation direction and / or the rotation amount with respect to the rotation center is displayed in the image information. Can be specified. Therefore, the driver visually recognizes the positional relationship between the target parking space 200 and the parking space setting frame F2, and uses the parking space setting frame F2 for the parking space 200 based on the parking space setting frame F2 constituting the positional relationship. Can be adjusted. As a result, the operability of position adjustment when setting the target parking space 200 can be improved.

  The second position adjustment method is a method of adjusting the position by revolving the parking space setting frame F2. This method is also particularly useful as a position adjustment method when the host vehicle V cannot be stopped parallel to the parking space 200.

  The control device 10 of the present embodiment includes a first input that designates a first input point set at a predetermined position of the obstacle avoidance frame F3, and a second input that designates a second input point other than the first input point. Accept. And the control apparatus 10 rotates the parking space setting frame F2 with respect to the bird's-eye view image 21 in the direction according to the rotation direction of the 2nd input point rotated and moved with respect to the 1st input point, and performs position adjustment. The first input point in the present embodiment is arranged outside the parking space setting frame F2 (not including a diagram showing the parking space setting frame F2). The first input point may be provided on the diagram of the obstacle avoidance frame F3 presented outside the parking space setting frame F2, or may be provided at the center of gravity (center) of the obstacle avoidance frame F3. In the present embodiment, an intersection of lines that are substantially orthogonal to each other on one of the two obstacle avoidance frames F3 provided in the left and right pair is defined as a first input point.

  6A and 6B are diagrams for describing an operation method for adjusting the position of the parking space setting frame F2. In the example shown in FIG. 6A, the first input point P1 is set at a predetermined position on the diagram of the obstacle avoidance frame F3, and the second input point P2A is an input point other than the first input point P1, It is set at a position different from the input point P1. As shown in FIG. 6A, the driver designates the first input point P1 with the thumb and performs the first input, and designates the second input point P2A with the index finger and performs the second input. Thereafter, as shown in FIG. 6A, the index finger is moved from the second input point P2A to the second input point P2B. Then, as shown in FIG. 6B, the parking space setting frame F2 revolves around the first input point P1 along the rotation direction from the second input point P2A to P2B.

  When performing the second input, the driver performs a linear second input point (P2A and P2B) from the second input point P2A to P2B along an arcuate operation flow line centered on the first input point P1. The second input operation is performed so as to trace the arc). That is, from the start of the second input to the end of the second input, the finger that indicates the second input point is in contact with the screen of the display 201. Instead of this operation, the driver individually taps one or two or more point-like second input points P2A and P2B that exist discretely on an arc-shaped operation flow line centered on the first input point P1 ( The second input operation may be performed. In this case, between the start of the second input and the end of the second input, the finger that points to the second input point P2 touches or separates the screen of the display 201.

  When receiving the position adjustment, the control device 10 superimposes the setting auxiliary information F including the parking space setting frame F2 and the obstacle avoidance frame F3 on the overhead image 21 and presents it on the input area of the display 201.

  The control device 10 changes the position of the parking space setting frame F2 based on the driver input information. As shown in FIG. 6B, the control device 10 is centered on the first input point P1 and centered on the first input point P1 according to the rotation direction from the second input point P2A to the second input point P2B. The parking space setting frame F2 is rotated (revolved) with respect to the bird's-eye view image 21. FIG. 6B shows a state after the parking space setting frame F2 and the obstacle avoidance frame F3 are rotated (revolved) with respect to the overhead image 21. As shown in FIG. 6B, the parking space setting frame F2 and the obstacle avoidance frame F3 have the same direction as the rotation direction from the second input point P2A to the second input point P2B (reverse to the first input point P1). Rotate clockwise.

  The control device 10 rotates the parking space setting frame F2 with respect to the sketch image 21 by a rotational movement amount corresponding to the rotational movement amount of the second input points P2A and P2B that rotate and move with respect to the first input point P1. That is, the rotation movement amount of the parking space setting frame F2 depends on the rotation amount when moving from the second input point P2A to P2B around the first input point P1 shown in FIG. 6A. Specifically, when the driver touches the second input point P2A and then moves the finger to the second input point P2B, it depends on the central angle between the second input point P2A and the second input point P2B. And rotate the parking space setting frame F2. When the central angle between the second input point P2A and the second input point P2B is 10 degrees, the parking space setting frame F2 may be rotated by 10 times or twice by 20 degrees. It is good or you may rotate by half 5 degrees.

  In the present embodiment, the rotation of the parking space setting frame F2 is a revolution centering on the first input point P1 set on the parking space setting frame F2, so that the operator (driver) has the rotation direction and the rotation amount. Easy to grasp. In other words, in the position adjustment operation of the parking space setting frame F2, the driver can rotate the second input point in what direction, in which direction, and how much the rotation amount, and how the parking space setting frame F2 is changed. It can be predicted whether it will rotate.

  As shown in the figure, in this embodiment, since the positional relationship between the parking space setting frame F2 and the obstacle avoidance frame F3 is kept constant, the obstacle avoidance frame F3 is also centered on the first input point P1. The second input points P2A and P2B are rotated in accordance with the rotation amount along the rotation direction.

  In the present embodiment, the bird's-eye view image 21 including the host vehicle V and the parking space 200, and the obstacle avoidance frame F3 and the parking space setting frame F2 arranged at predetermined positions with respect to the host vehicle V are overlapped. The image information is presented to the driver, and in the image information, the driver can specify the rotation center of the parking space setting frame F2 in the common coordinate system, and can also specify the rotation direction and / or the rotation amount with respect to the rotation center. For this reason, the driver visually recognizes the positional relationship between the target parking space 200 and the parking space setting frame F2, while referring to the obstacle avoidance frame F3 constituting the positional relationship, the parking space setting frame F2 for the parking space 200. Can be adjusted. As a result, the operability of position adjustment when setting the target parking space 200 can be improved.

  The third position adjustment method is a method of adjusting the position by moving the parking space setting frame F2 in parallel. This method is a position when the vehicle is stopped before the target parking space 200, or when the vehicle has gone too far from the target parking space 200, or when the vehicle is too far from the target parking space 200 in the vehicle width direction. This is particularly useful as an adjustment method.

The control device 10 of the present embodiment has a first input that specifies the first input point set at a predetermined position of the setting auxiliary information F, and a second input that specifies a second input point other than the first input point. Accept. Then, the controller 10 adjusts the position by moving the parking space setting frame F2 in the direction in which the second input point moves relative to the first input point (the direction in which the position of the second input point changes over time). I do. The auxiliary setting information F of the present embodiment includes at least a parking space setting frame F2. In this embodiment, the obstacle avoidance frame F3 displayed at the predetermined position outside the parking space setting frame F2 is included. The first input point may be set on the boundary line of the parking space setting frame F2, or may be set on the diagram of the obstacle avoidance frame F3. In the present embodiment, a point located on the boundary line of the parking space setting frame F2 and located at the center of the front surface of the vehicle (front bumper side) during parking is defined as the first input point. When setting on the diagram of the obstacle avoidance frame F3, an intersection point of the substantially orthogonal diagram may be defined as the first input point. The number of first input points is not limited to one and may be plural.

  7A and 7B are diagrams for explaining an operation method for adjusting the position of the parking space setting frame F2. In the example shown in FIG. 7A, the first input point R1 is set at a predetermined position on the boundary line of the parking space setting frame F2, and the second input point R1 ′ is an input point other than the first input point R1, It is set at a position different from the input point R1. As shown in FIG. 7A, the driver designates the first input point R1 with the index finger, performs the first input, moves the same index finger, designates the second input point R1 ′, and performs the second input. FIG. 7A is an example in which two first input points and two second input points are set. The driver performs the first input by specifying the first input point R2A with the middle finger in addition to the operation with the index finger described above. , Move the same middle finger to specify the second input point R2B and perform the second input. The finger to be operated is not particularly limited, and the first input point R1 and the second input point R1 ′ may be designated with the thumb, and the first input point R2A and the second input point R2B may be designated with the index finger. By providing a plurality of first input points, second input points, and operation flow lines between them, the movement of the finger of the driver can be stabilized and an accurate input operation can be performed.

  When performing the second input, the driver performs a plurality of second input points along a linear operation flow line (indicated by a broken line in the drawing) connecting the first input point R1 and the second input point R1 ′. Are sequentially traced in a linear manner. In other words, the driver's finger is in contact with the screen of the display 201 until the second input point R1 ′ is instructed after the first input point R1 is indicated. Instead of this operation, the driver performs one or two or more point-like second input points R1 ′ that are discretely present on a substantially linear operation flow line from the first input point R1 to the second input point R1 ′. The second input operation may be performed by tapping (hitting) sequentially. In this case, during the period from the start of the second input to the end of the second input, the finger that points to the second input point R2 touches or separates the screen of the display 201.

  When receiving the position adjustment, the control device 10 superimposes the setting auxiliary information F including the parking space setting frame F2 and the obstacle avoidance frame F3 on the overhead image 21 and presents it on the input area of the display 201.

  The control device 10 changes the position of the parking space setting frame F2 based on the driver input information. As illustrated in FIG. 7B, the control device 10 moves the parking space setting frame F2 along the direction in which the second input point R1 ′ is present with respect to the first input point R1. FIG. 7B shows a state after the parking space setting frame F2 and the obstacle avoidance frame F3 are moved in the −y direction with respect to the overhead image 21. As shown in FIG. 7B, the parking space setting frame F2 and the obstacle avoidance frame F3 move from the first input point R1 to the presence direction (−y direction) of the second input point R1 ′.

  The control device 10 moves the parking space setting frame F2 with respect to the hand-drawn image 21 by a moving amount corresponding to the distance between the first input point R1 and the second input point R1 ′. That is, the moving amount of the parking space setting frame F2 depends on the distance between the first input point R1 and the second input point R1 ′ shown in FIG. 7A.

  In this embodiment, since the parking space setting frame F2 moves along the moving direction of the first input point Q1 set on the parking space setting frame F2, it is easy for the operator (driver) to grasp the moving direction. is there. That is, the driver can predict in which direction the parking space setting frame F2 moves by the input of the first input point R1 and the second input point R1 ′.

  As shown in the figure, in this embodiment, since the positional relationship between the parking space setting frame F2 and the obstacle avoidance frame F3 is kept constant, the obstacle avoidance frame F3 is also the first input point R1 with respect to the first input point R1. It moves according to the distance along the direction in which the two input points R1 ′ exist.

  The example in which the setting auxiliary information F (the parking space setting frame F2, the obstacle avoidance frame F3) is moved along the y direction in the figure has been described above. However, as illustrated in FIGS. 8A and 8B, the setting auxiliary information F (parking information F It is also possible to move the space setting frame F2 and the obstacle avoidance frame F3) along the x direction in the figure. In the example shown in FIGS. 8A and 8B, the first input point R3 is set at a predetermined position on the boundary line of the parking space setting frame F2, and the second input point R3 ′ is an input point other than the first input point R3. The first input point R3 is set at a different position. As shown in FIG. 8A, the driver designates the first input point R3 with the index finger, performs the first input, moves the same index finger, designates the second input point R3 ', and performs the second input. At the same time, the first input point R4A and the second input point R4B are operated with the thumb. With this operation, the setting auxiliary information F (the parking space setting frame F2, the obstacle avoidance frame F3) moves to the right (+ x direction) with respect to the overhead image 21.

  In this embodiment, the bird's-eye view image 21 including the host vehicle V and the parking space 200 and the parking space setting frame F2 (an obstacle avoidance frame F3 as necessary) arranged at a predetermined position with respect to the host vehicle V are provided. The image information is superimposed and presented to the driver as one image information. In the image information, the driver designates the movement start point of the parking space setting frame F2 in the common coordinate system, and the movement direction with respect to the movement start point and / or You can specify the amount of movement. Therefore, the driver recognizes the positional relationship between the parking space 200 and the parking space setting frame F2 with reference to the parking space setting frame F2, and the positional deviation of the parking space setting frame F2 constituting the positional relationship with respect to the parking space 200. Can be adjusted. As a result, the operability of position adjustment when setting the target parking space 200 can be improved.

  As shown in FIG. 5A, FIG. 6A and FIG. 7A, when the position adjustment process of the parking space setting frame F2 is executed, the first input point marks Q1, P1 and R1 are superimposed on the overhead image 21 and presented. Similarly, second input point marks Q2A, Q2B, P2A, P2B, and R1 ′ indicating input positions for receiving the second input are presented superimposed on the overhead image 21. Although the display mode is not particularly limited, in the present embodiment, the first input point mark and the second input point mark are displayed as marks of different modes. Specifically, the first input point mark is indicated by a circular graphic, and the second input point mark is indicated by a hollow circular graphic. The form of the graphic is not particularly limited, and can be displayed as text. As a result, the driver can intuitively understand where the rotation center is, where to rotate and where is the movement start point, so that the operability of the driver is improved. be able to.

  Further, the control device 10 of the present embodiment includes an operation flow line mark (indicated by an arrow in the figure) indicating the operation flow line connecting the two second input point marks Q2A and Q2B, P2A and P2B, and the first input point mark. An operation flow line mark (indicated by an arrow in the figure) indicating an operation flow line connecting R1 and the second input point mark R1 ′ is superimposed on the overhead image 21 and presented. As a result, the driver can intuitively understand the operation flow line to be rotated or translated, so that the operability of the driver can be improved.

  Thus, in this embodiment, the position of the parking space setting frame F2 with respect to the target parking space 200 can be adjusted by moving the parking space setting frame F2 with respect to the overhead image 21. Hereinafter, specific processing examples will be described based on the drawings.

  9A to 9C are diagrams for explaining a position adjustment operation when the parking space setting frame F2 is rotated to adjust the position of the parking space setting frame F2 to the position of the target parking space 200. FIG.

  FIG. 9A shows a presentation image when the driver cannot stop the host vehicle V in parallel with the parallel direction of the parking space 200. The presented image includes a target parking space 200, an overhead image 21 including an image of another vehicle, an icon V of the host vehicle, a parking space setting frame F2, and an obstacle avoidance frame F3. 9A, the vehicle length direction of the host vehicle V in the overhead image 21 is not parallel to the parking space 200, and the vertical and horizontal directions of the parking space setting frame F2 are different from the vertical and horizontal directions of the parking space 200. (bent). In this state, when the parking assist process is executed and the host vehicle V is guided to the parking space setting frame F2, the host vehicle V enters the target parking space 200 in a bent state, and the vehicle As a result, the section protrudes from the target parking space 200.

  In such a case, the parking assistance apparatus 100 of this embodiment can adjust by rotating the position of the parking space setting frame F2 on the bird's-eye view image 21. Specifically, the driver designates the first input point Q1 shown in FIG. 9B to perform the first input, designates the second input point Q2A, and performs the second input along the operation flow line mark (arrow). A second input is performed by tracing the operation flow line from the point Q2A to the second input point Q2B (or tapping the second input points Q2A and Q2B). Then, since the parking space setting frame F2 rotates about the first input point Q1, the position of the parking space setting frame F2 can be adjusted to the position of the target parking space 200 as shown in FIG. 9C.

  Thus, even if the parking space setting frame F2 cannot be stopped so as to overlap the target parking space 200, the position of the parking space setting frame F2 with respect to the target parking space 200 can be adjusted. The host vehicle V can be guided to the target parking space 200 where the driver wants to park without correcting the V stop position. Moreover, on the bird's-eye view image 21 on which the parking space setting frame F2 and the target parking space 200 are displayed, the position of the parking space setting frame F2 can be corrected using the common coordinate system and the parking space setting frame F2 as a reference. it can. 9A to 9C show an example in which the position of the parking space setting frame F2 is adjusted by rotating the parking space setting frame F2, but the position adjustment method for revolving the parking space setting frame F2 described above, It is possible to use a position adjustment method for moving the parking space setting frame F2 on the bird's-eye view image 21 surface.

  FIGS. 10A to 10C are diagrams for explaining a position adjustment operation when the position of the parking space setting frame F2 is adjusted to the position of the target parking space 200 by revolving the parking space setting frame F2.

  FIG. 10A shows a presentation image when the driver cannot stop the host vehicle V in parallel with the parallel direction of the parking space 200. The presented image includes a target parking space 200, an overhead image 21 including an image of another vehicle, an icon V of the host vehicle, a parking space setting frame F2, and an obstacle avoidance frame F3. As shown in FIG. 10A, the vehicle length direction of the host vehicle V in the overhead image 21 is not parallel to the parking space 200, and the vertical and horizontal directions of the parking space setting frame F2 are different from the vertical and horizontal directions of the parking space 200. . In this state, when the parking assist process is executed and the host vehicle V is guided to the parking space setting frame F2, the host vehicle V enters the target parking space 200 in a bent state, and the vehicle As a result, the section protrudes from the target parking space 200.

  In such a case, the parking assistance apparatus 100 of this embodiment can adjust by revolving the position of the parking space setting frame F2 on the bird's-eye view image 21. Specifically, the driver designates the first input point P1 shown in FIG. 10B, performs the first input, designates the second input point P2A, and reaches the second input point P2B from the second input point P2A. The second input is performed by tracing the operation flow line (or tapping the second input points P2A and P2B). Then, since the parking space setting frame F2 revolves around the first input point P1, the position of the parking space setting frame F2 can be adjusted to the position of the target parking space 200 as shown in FIG. 10C.

  Thus, even if the parking space setting frame F2 cannot be stopped so as to overlap the target parking space 200, the position of the parking space setting frame F2 with respect to the target parking space 200 can be adjusted. The host vehicle V can be guided to the target parking space 200 where the driver wants to park without correcting the V stop position. In addition, on the bird's-eye view image 21 on which the parking space setting frame F2, the obstacle avoidance frame F3, and the target parking space 200 are displayed, a common coordinate system is used and the parking space setting frame F2 is set based on the obstacle avoidance frame F3. The position can be corrected. In the example shown in FIGS. 10A to 10C, an example of adjusting the position of the parking space setting frame F <b> 2 by revolving the parking space setting frame F <b> 2 is shown, but the position adjustment method for rotating the parking space setting frame F <b> 2 described above, It is possible to use a position adjustment method for moving the parking space setting frame F2 on the bird's-eye view image 21 surface.

  FIGS. 11A to 11C illustrate a position adjustment operation when the position of the parking space setting frame F2 is adjusted to the position of the target parking space 200 by linearly moving the parking space setting frame F2 on the overhead image 21. FIG.

  FIG. 11A shows an example of a presentation image when the driver cannot stop the host vehicle V at the position of the parking space 200. The presented image includes a target parking space 200, an overhead image 21 including an image of another vehicle, an icon V of the host vehicle, a parking space setting frame F2, and an obstacle avoidance frame F3. As shown in FIG. 11A, the stop position of the host vehicle V in the bird's-eye view image 21 is not beside the parking space 200, and the center position of the parking space setting frame F2 is closer to the front side (vehicle rear side) than the center position of the parking space 200. It's off. In this state, when the parking assistance process is executed and the host vehicle V is guided to the parking space setting frame F2, the vehicle enters the parking space next to the target parking space 200, and a part of the vehicle is parked in the target parking space. As a result, the space 200 protrudes.

In such a case, the parking assistance apparatus 100 according to the present embodiment adjusts the position of the parking space setting frame F2 on the overhead image 21 so that the parking space setting frame F2 can be displayed without moving the host vehicle V. It can be adjusted to the target parking space 200. Specifically, the driver specifies the first input point R1 shown in FIG. 11B, performs a first input, a second input point R1' by sliding a finger along the operation flow line mark (arrow) Specify and make the second input. You may tap 1st input points R1 and R1 '. Then, since the parking space setting frame F2 moves in parallel in the y direction from the first input point R1 to R1 ′, the position of the parking space setting frame F2 can be adjusted to the position of the target parking space 200 as shown in FIG. 11C. it can.

  Thus, even if the parking space setting frame F2 cannot be stopped so as to overlap the target parking space 200, the position of the parking space setting frame F2 with respect to the target parking space 200 can be adjusted. The host vehicle V can be guided to the target parking space 200 where the driver wants to park without correcting the V stop position. Moreover, on the bird's-eye view image 21 on which the parking space setting frame F2 and the target parking space 200 are displayed, the position of the parking space setting frame F2 can be corrected using the common coordinate system and the parking space setting frame F2 as a reference. it can. 11A to 11C show an example in which the position of the parking space setting frame F2 is adjusted by translating the parking space setting frame F2 along the y direction in the figure. It is also possible to use a position adjustment method for translating F2 along the y direction in the drawing and a position adjustment method for rotating or revolving the parking space setting frame F2.

  When the position of the parking space setting frame F2 overlaps the target parking space 200 by the position adjustment method described above, the target parking space setting process is executed.

  Here, returning to the flowchart of FIG. 2, the processing after step S106 will be described. In step S106, the control device 10 performs a target parking space setting process. The control device 10 of the parking assistance device 100 of the present embodiment parks the host vehicle V in the parking space 200 corresponding to the position of the parking space setting frame F2 included in the setting auxiliary information F presented on the touch panel display 201. The target parking space 200 is set. When setting the target parking space 200, the driver may input his / her intention to make a decision. After the target parking space 200 is determined, the processes after step S107 are executed.

  In the next step S107, the control device 10 of the parking assistance device 100 calculates a parking route for moving the host vehicle V to the selected target parking space 200 in the selected parking mode. Specifically, the parking assistance device 100 activates the parking assistance control unit, stops the host vehicle V, and determines the parking route based on the positional relationship between the current position where the parking assistance starts and the position of the target parking space 200. calculate. The parking route is stored in a memory (ROM) one by one corresponding to each of parallel parking, parallel parking, and diagonal parking, and the route corresponding to the selected parking mode is read, and the parking assistance process starts. A parking route is calculated based on the positional relationship between the position of the vehicle V and the position of the target parking space 200. Although not particularly limited, the parking assistance control unit calculates the parking position of the host vehicle V, that is, the curve from the parking assistance start position to the turn-back position and the curve from the turn-back position to the target parking space 200 as the parking route. . Although not particularly limited, the parking assistance device 100 selects the target parking space 200, and when the driver relaxes the brake pedal pressure and the predetermined brake pressure is released, the acquired position and parking mode of the target parking space 200 are acquired. When execution of the parking support process based on the selection information is determined and the driver depresses the accelerator pedal, the execution of the support for the operation of parking the host vehicle V in the target parking space 200 along the calculated parking route is started.

  In step S108, the parking assistance apparatus 100 of the present embodiment executes a parking assistance process. The parking assist device 100 according to the present embodiment controls the steering of the host vehicle V so that the host vehicle V moves along the parking path. The parking assistance device 100 feeds the output value of the steering angle sensor 51 of the steering 50 to the drive system 40 of the own vehicle V such as an EPS motor while feeding back the output value of the steering angle sensor 51 of the steering 50 so that the movement locus of the own vehicle V matches the calculated parking route. The command signal is calculated, and the command signal is sent to the drive system 40 or the vehicle controller 30 that controls the drive system 40.

  12A and 12B show an example of a specific movement of the host vehicle V in the parking support process. The parking assist device 100 according to the present embodiment allows the driver to move the host vehicle V to the parking space 200 along the parking route Q calculated based on the current position of the host vehicle V and the position of the parking space 200. The accelerator / brake operation is automatically controlled based on the designated control vehicle speed (set vehicle speed), and the operation of the steering device 50 is automatically controlled according to the vehicle speed. That is, the driver does not need to operate the steering wheel at the time of parking assistance according to the present embodiment. In addition, the method of operation control of the own vehicle at the time of parking is not particularly limited, and both the accelerator / brake and the accelerator / brake operation can be automatically performed.

  As illustrated in FIG. 12A, the driver adjusts the position of the host vehicle V so that the parking space setting frame F <b> 2 overlaps the target parking space 200. By this operation, the target parking space 200 is set. The host vehicle V is stopped at a position V0 next to the target parking space 200. Thereafter, when the driver depresses the accelerator, the parking assist operation is started. Steering is automatically controlled. The host vehicle V follows the parking route Q1 and moves diagonally forward to the right. The driver depresses the brake and temporarily stops the host vehicle V at the position V1. Subsequently, as shown in FIG. 12B, when the driver switches the gear to the back position and depresses the accelerator, the vehicle V retreats from the position V1 along the parking route Q2, passes through the position V2, and passes through the parking space. Enter 200 and stop at position V3. Steering is automatically controlled while moving on the parking route Q2. In this parking assistance execution process, the parking assistance device 100 controls the driving device 40 based on a preset vehicle speed that is calculated in advance so that the host vehicle V moves along the parking route Q1, and the preset steering angle calculated in advance. The steering device 50 is controlled based on the above.

  Of course, the calculated parking route is displayed on the display 201 or the like without performing automatic steering, and the steering amount of the steering device 50 and the turning timing, brake or accelerator so that the movement locus of the host vehicle V coincides with the parking route. Parking assistance can also be performed by instructing the operation timing. In addition, the content disclosed at the time of filing can be applied as appropriate for the contents of parking assistance.

  The parking assistance device 100 of the present embodiment configured and operating as described above has the following effects.

  [1] According to the parking assistance device 100 of the present embodiment of the present invention, the overhead image is superimposed on the first input point specified by the first input and the second input according to the change in the position of the second input point with respect to the first input point. Since the position of the set parking space setting frame can be changed based on the first input point, the driver determines the position of the host vehicle, the position of the parking space, and the position of the parking space setting frame that are presented in the overhead view image. While confirming with one piece of image information, the position of the parking space setting frame can be adjusted using the common coordinate system on the image information. As a result, the operability of position adjustment when setting the target parking space can be improved.

  [2] According to the parking assist device 100 of the present embodiment of the present invention, according to the rotation direction of the second input point with respect to the first input point specified by the first input and the second input, the parking space setting frame The position can be rotated around the first input point set at a predetermined position of the parking space setting frame. For this reason, the driver confirms the common coordinate system on the image information while confirming the position of the own vehicle, the position of the parking space, and the position of the parking space setting frame presented in the overhead image with one image information. The direction of rotation and the position of the parking space setting frame can be adjusted by arbitrarily specifying the rotation direction. As a result, the operability of position adjustment when setting the target parking space can be improved.

[3] According to the parking assistance device 100 of the present embodiment of the present invention, the first input point is set on the parking space setting frame or inside the parking space setting frame, so that the parking space setting frame itself is the center of rotation. Since the parking space setting frame can be rotated, the above-described effects are exhibited. In particular, the position of the parking space setting frame may be left as it is, but if only the direction (direction) is to be adjusted, it can be adjusted by a single operation.

  [4] According to the parking assist device 100 of the present embodiment of the present invention, the parking space setting frame F2 is rotated with respect to the overhead image 21 in accordance with the rotational movement amount of the second input point with respect to the first input point. In addition to the above-described effects, the driver adjusts the amount of rotation of the parking space setting frame F2 by adjusting the amount of rotation of the second input point according to the amount of deviation of the parking space setting frame F2 from the target parking space 200. can do. As a result, the operability of position adjustment when setting the target parking space can be improved.

  [5] According to the parking assist device 100 of the present embodiment of the present invention, the parking space setting frame F2 is obtained by an operation of tracing the second input point along the arc-shaped operation flow line centering on the first input point. Since the position of the parking space setting frame F2 is moved, the position after the movement can be easily predicted.

  [6] According to the parking assistance apparatus 100 of the present embodiment of the present invention, a parking space is obtained by tapping a plurality of second input points that are discretely present on an arc-shaped operation flow line centered on the first input point. Since the setting frame F2 is rotated, the position after the movement of the parking space setting frame F2 can be easily predicted.

  [7] The parking assist device 100 of the present embodiment of the present invention superimposes the parking space setting frame F2 and the obstacle avoidance frame F3 displayed at a predetermined position outside the parking space setting frame F2 on the overhead view image. Thus, the driver can confirm the positional relationship between the obstacle present around the parking space setting frame F2 and the host vehicle by one visual observation. As a result, the target parking space 200 can be set smoothly.

  [8] The parking assistance apparatus 100 according to the present embodiment of the present invention performs the position adjustment on the overhead image 21 while maintaining the positional relationship between the parking space setting frame F2 and the obstacle avoidance frame F3. Since the vehicle is moved, the driver can confirm the distance between the obstacle present around the parking space setting frame F2 and the own vehicle by visual observation at the time of position adjustment. As a result, the target parking space 200 can be set smoothly.

  [9] The parking assist device 100 according to the present embodiment of the present invention displays the parking space setting frame F2 in a predetermined first color and displays the obstacle avoidance frame F3 in a second color different from the first color. Therefore, the driver can easily identify the parking space setting frame F2 and the obstacle avoidance frame F3 displayed at the same time when the position is adjusted.

  [10] The parking assist device 100 according to the present embodiment of the present invention presents the first input point mark superimposed on the bird's-eye view image 21 when performing position adjustment, so that the driver can easily locate the position of the first input point. Can be recognized.

  [11] Since the parking assistance device 100 according to the present embodiment of the present invention performs position adjustment, the second input point mark is superimposed on the overhead image 21 and presented in a manner different from the first input point mark. The driver can easily identify the first input point and the second input point, and can easily recognize the position of the first input point and the position of the second input point different from the position of the first input point. it can.

  [12] The parking assistance apparatus 100 according to the present embodiment of the present invention superimposes an operation flow line mark indicating an operation flow line connecting two second input point marks on the overhead image 21 when performing position adjustment. By presenting, it is possible to guide the second input operation of the driver. Since the driver only has to move the finger along the presented operation flow line mark, the driver can intuitively understand the operation to be performed.

  [13] According to the parking assistance device 100 of the present embodiment of the present invention, the parking assistance device 100 is superimposed on the overhead image according to the rotation direction of the second input point with respect to the first input point specified by the first input and the second input. Since the position of the parking space setting frame can be revolved around the first input point set at the predetermined position of the parking space setting frame as a center of rotation, the driver can park the vehicle with the position of the vehicle presented in the overhead image. While confirming the position of the space and the position of the parking space setting frame with one image information, on the image information, a predetermined rotation center (corresponding to the position of the parking space setting frame using a common coordinate system ( The position of the parking space setting frame can be adjusted by arbitrarily designating the rotation direction on the basis of the first input point). As a result, the operability of position adjustment when setting the target parking space can be improved.

  [14] According to the parking assistance apparatus 100 of the present embodiment of the present invention, the overhead is superimposed on the overhead image according to the moving direction of the second input point with respect to the first input point specified by the first input and the second input. Since the position of the parking space setting frame can be moved with reference to the first input point set at the predetermined position of the parking space setting frame, the driver can determine the position of the vehicle and the parking space presented in the overhead image. The first input point associated with the position of the parking space setting frame using the common coordinate system is used as a reference on the image information while confirming the position of the parking space and the position of the parking space setting frame with one image information. As the movement direction can be arbitrarily specified, the position of the parking space setting frame can be adjusted. As a result, the operability of position adjustment when setting the target parking space can be improved.

  It should be noted that all the embodiments described above are described for facilitating the understanding of the present invention, and are not described for limiting the present invention. Therefore, each element disclosed in the above embodiment is intended to include all design changes and equivalents belonging to the technical scope of the present invention.

  In this specification, as one aspect of the parking assistance device according to the present invention, the parking assistance device 100 mounted on the host vehicle V, the vehicle controller 30, the drive system 40, the steering device 50, and various sensors 60 are provided. Although the parking assistance system 1000 provided is demonstrated, it is not limited to this.

  Moreover, in this specification, as one aspect | mode of a parking assistance apparatus provided with a captured image acquisition means, an image generation means, a parking information presentation means, a position adjustment means, a target parking space setting means, and a parking assistance means. The parking assistance device 100 including the control device 10 that executes the captured image acquisition function, the image generation function, the parking information presentation function, the position adjustment function, the target parking space setting function, and the parking assistance function will be described. It is not limited to.

1000 ... Parking assistance system 100 ... Parking assistance device
10 ... Control device 11 ... CPU
12 ... ROM
13 ... RAM
Code group including F, F ... setting auxiliary information F2 ... parking space setting frame F3 ... obstacle avoiding frame 20 ... input / output device 201 ... touch panel type display 1a-1d ... vehicle-mounted camera 2 ... image processing device 30 ... vehicle controller 40 ... Drive system 50 ... Steering device 51 ... Steering angle sensor 60 ... Vehicle speed sensor and other various sensors 200 ... Each parking space, target parking space V ... Vehicle

Claims (12)

A parking support device that supports a parking operation for moving the vehicle to a target parking space,
Captured image acquisition means for acquiring captured images around the host vehicle;
Based on the acquired captured image, image generating means for generating an overhead image when the surrounding state including the own vehicle and a parking space in which the own vehicle is parked is viewed from an upper viewpoint of the own vehicle;
Parking information presenting means for superimposing setting auxiliary information including a parking space setting frame displayed at a predetermined position with respect to the host vehicle in the overhead image on the overhead image and presenting it on an input area of a display;
A first input that designates a first input point that is a position on or within the parking space setting frame and a second input that designates a second input point that is different from the first input point The position where the parking space setting frame is rotated around the first input point in the direction corresponding to the rotation direction of the second input point that rotates and moves relative to the first input point. Adjusting means;
A target parking space setting means for setting a parking space corresponding to the position of the adjusted parking space setting frame as a target parking space in which the host vehicle is parked;
A parking support device that supports an operation of parking the host vehicle in the target parking space. The position adjustment means adjusts the position by rotating the parking space setting frame with respect to the overhead image with a rotational movement amount corresponding to the rotational movement amount of the second input point that rotates relative to the first input point. The parking assistance device according to claim 1 , wherein Operation according to the second input, to claim 1 or 2, characterized in that the operation of tracing the second input point into a line shape along the arcuate operation flow line around the first input point The parking assistance device described. The operation related to the second input is an operation of tapping one or two or more point-like second input points that exist discretely on an arc-shaped operation flow line centered on the first input point. The parking assistance device according to any one of claims 1 to 3 , wherein The parking information presenting means is configured to superimpose setting auxiliary information including a parking space setting frame and an obstacle avoidance frame displayed at a predetermined position outside the parking space setting frame on the overhead image, and an input area of the display The parking assistance device according to any one of claims 1 to 4 , wherein the parking assistance device is presented in the above. When the position adjustment is performed, the parking information presentation unit maintains the positional relationship between the parking space setting frame and the obstacle avoidance frame, and the parking space setting frame and the obstacle avoidance frame are The parking support apparatus according to claim 5 , wherein the parking support apparatus is moved with respect to the overhead image. The parking information presenting means, and displays the parking space setting frame in a predetermined first color, claim and displaying a different second color and the obstacle avoidance frame first color 5 Or the parking assistance apparatus of 6 . The parking information presenting means, according to any one of claims 1 to 7, wherein presenting the first input point mark indicating the input position for accepting said first input is superimposed on the overhead image Parking assistance device. The parking information presenting means, wherein said first input point mark different from the embodiment, and wherein the second input point mark indicating the input position for accepting said second input to present superimposed on the overhead image Item 9. The parking assistance device according to item 8 . The parking support device according to claim 9 , wherein the parking information presenting unit presents an operation flow line mark indicating an operation flow line of the second input point mark superimposed on the overhead image. The position adjusting means receives a first input for designating a first input point set outside the parking space setting frame and a second input for designating a second input point other than the first input point; The position adjustment is performed by rotating the parking space setting frame around the first input point in a direction corresponding to a rotation direction of the second input point that rotates and moves with respect to the first input point. The parking assistance device according to any one of claims 1 to 10 . The position adjusting means receives a first input for designating a first input point set at a predetermined position of the setting auxiliary information and a second input for designating a second input point other than the first input point; a direction in which the second input point with respect to the first input point is moved, according to any one of claims 1 to 11, characterized in that adjusting the position by moving the parking space setting frame Parking assistance device.

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