JP2019196116A - Parking support device and automatically parkable vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To maintain a braking state of a vehicle even after a driver releases his foot from a brake pedal after performing an operation for instructing to start parking assistance control. SOLUTION: An automatic parking control unit 11 that performs a parking operation of a vehicle at a determined target parking position, a parking start instruction detection unit 12 that receives a start instruction of a parking operation by the operation of the automatic parking control unit 11, and a start instruction When the vehicle stops during the period from the reception to the start of the parking operation by the operation of the automatic parking control unit 11, the braking for instructing the automatic brake hold control unit 44 for holding the braking of the vehicle to hold the braking of the vehicle. A holding instruction unit 13 is provided. [Selection diagram] Figure 1

Description

  The present invention relates to a parking assist device and a vehicle capable of automatic parking.

  Patent Documents 1 and 2 disclose a parking assistance ECU that performs parking assistance control that recognizes a situation around a vehicle with a camera and that can guide the vehicle to a target parking position.

Japanese Patent No. 5834058 Japanese Patent No. 597724

However, in the parking assistance control of Patent Literatures 1 and 2, after the driver performs an operation to start the parking assistance control control and stops the vehicle, the following problems may occur. That is, the driver may take his foot off the brake pedal in anticipation of the start of parking assistance control that can automatically guide the vehicle to the target parking position. Therefore, there is a possibility that the vehicle moves in an unintended manner by the driver and surprises the driver.
An object of the present invention is to maintain a braking state of a vehicle even if a driver removes his / her foot from a brake pedal after performing an operation to instruct the start of parking assist control.

  The parking assist device of the present invention includes an automatic parking control unit that performs a parking operation of a vehicle at a target parking position determined by predetermined means, and a parking activation instruction that receives an activation instruction for the parking operation by the operation of the automatic parking control unit. When the vehicle stops between the detection unit and the start of the parking operation by the operation of the automatic parking control unit from reception of the activation instruction, to the automatic braking holding control unit that holds the braking of the vehicle And a braking / holding instruction unit for instructing execution of the braking / holding.

  According to the present invention, the brake state of the vehicle is maintained even if the driver removes his / her foot from the brake pedal after performing an operation to instruct the start of parking assist control.

It is a block diagram which shows the system configuration | structure of this embodiment centering on the automatic parking control unit which concerns on one Embodiment of this invention. It is a top view which shows the mounting position of the camera and sonar of the vehicle carrying the automatic parking control unit which concerns on one Embodiment of this invention. It is a top view of the parking lot explaining the situation where the vehicle carrying the automatic parking control unit which concerns on one Embodiment of this invention searches for the space for parking. It is a top view of the parking lot explaining the situation where the vehicle carrying the automatic parking control unit which concerns on one Embodiment of this invention searches for the space for parking. It is a top view of the parking lot explaining the situation where the vehicle carrying the automatic parking control unit which concerns on one Embodiment of this invention searches for the space for parking. It is a flowchart explaining the process which the automatic parking control unit which concerns on one Embodiment of this invention performs. It is a flowchart explaining the process which the automatic parking control unit which concerns on one Embodiment of this invention performs. It is a top view of the parking lot explaining the process which the automatic parking control unit which concerns on one Embodiment of this invention performs. It is a top view of the parking lot explaining the process which the automatic parking control unit which concerns on one Embodiment of this invention performs. It is a top view of the parking lot explaining the process which the automatic parking control unit which concerns on one Embodiment of this invention performs. It is a top view of the parking lot explaining the process which the automatic parking control unit which concerns on one Embodiment of this invention performs. It is a top view of the selection screen displayed on a touch panel by the process which the automatic parking control unit concerning one embodiment of the present invention performs. It is a top view of a parking lot explaining a case where a shift operation is performed during operation of an automatic parking function by an automatic parking control unit concerning one embodiment of the present invention. It is a top view of a parking lot explaining a case where a shift operation is performed during operation of an automatic parking function by an automatic parking control unit concerning one embodiment of the present invention. It is a top view of a parking lot explaining a case where a shift operation is performed during operation of an automatic parking function by an automatic parking control unit concerning one embodiment of the present invention. It is a top view of a parking lot explaining a case where a shift operation is performed during operation of an automatic parking function by an automatic parking control unit concerning one embodiment of the present invention. It is a top view of a parking lot explaining a case where a shift operation is performed during operation of an automatic parking function by an automatic parking control unit concerning one embodiment of the present invention. It is a top view of a parking lot explaining a case where a shift operation is performed during operation of an automatic parking function by an automatic parking control unit concerning one embodiment of the present invention. It is a top view of a parking lot explaining a case where a shift operation is performed during operation of an automatic parking function by an automatic parking control unit concerning one embodiment of the present invention. It is a top view of a parking lot explaining a case where a shift operation is performed during operation of an automatic parking function by an automatic parking control unit concerning one embodiment of the present invention. It is a top view of the parking lot which demonstrates another example at the time of shifting operation during operation | movement of the automatic parking function by the automatic parking control unit which concerns on one Embodiment of this invention with time. It is a top view of the parking lot which demonstrates another example at the time of shifting operation during operation | movement of the automatic parking function by the automatic parking control unit which concerns on one Embodiment of this invention with time. It is a top view of the parking lot which demonstrates another example at the time of shifting operation during operation | movement of the automatic parking function by the automatic parking control unit which concerns on one Embodiment of this invention with time. It is a top view of the parking lot which demonstrates over time another example at the time of shifting operation during operation | movement of the automatic parking function by the automatic parking control unit which concerns on one Embodiment of this invention. It is a top view of the parking lot which demonstrates another example at the time of shifting operation during operation | movement of the automatic parking function by the automatic parking control unit which concerns on one Embodiment of this invention with time.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the following description of the front, rear, left and right directions follow the arrows in the figure.
FIG. 1 is a block diagram showing a system configuration of the present embodiment with the automatic parking control unit 1 as the center. FIG. 2 is a top view of a vehicle 100 equipped with the system of FIG.

  The automatic parking control unit 1 is an automatic parking ECU (Electronic Control Unit) and implements the parking assist device of the present invention. The automatic parking control unit 1 is configured around a microcomputer, and realizes the functions of the following various control units by processing executed based on the control program. That is, the automatic parking control unit 1 executes the function of the automatic parking control unit 11. The automatic parking control unit 11 also executes the functions of the parking position detection unit 11a and the target parking position detection unit 11b. The automatic parking control unit 1 also executes the functions of a parking activation instruction detection unit 12, a braking / holding instruction unit 13, and a braking / holding continuation determination unit 14. Furthermore, the automatic parking control unit 1 also executes the functions of the control holding cancellation instruction unit 15, the first parking operation interruption unit 16, the second parking operation interruption unit 17, and the restart instruction unit 18. Details of the processes executed by these units will be described later.

  A camera group 21 and a sonar group 22 are connected to the automatic parking control unit 1. In addition, each part connected to the automatic parking control unit 1 (the connection is shown by a diagram) may be directly connected to the automatic parking control unit 1 or a CAN (Controller Area Network). ) May be connected.

  The camera group 21 is a plurality of cameras mounted on the vehicle 100 shown in FIG. That is, the vehicle 100 includes a front camera 21 </ b> F that is provided in front of the vehicle 100 and images the front side of the vehicle 100. In addition, the vehicle 100 includes a rear camera 21 </ b> R that is provided behind the vehicle 100 and images the rear side of the vehicle 100. Furthermore, the vehicle 100 includes a side camera 21RF that is provided in front of the right side portion of the vehicle 100 and images the right side portion of the vehicle 100. The vehicle 100 includes a side camera 21LF that is provided in front of the left side of the vehicle 100 of the vehicle 100 and images the left side of the vehicle 100. Note that it is desirable that the side cameras 21RF and 21LF be provided at the front end portion of the door mirror or apart from the door mirror because the door mirror does not appear greatly in the camera image. Of course, you may provide in a different place in some distance from a door mirror.

  The sonar group 22 is a plurality of sonar mounted on the vehicle 100 shown in FIG. That is, the vehicle 100 includes four front sonars 22F arranged in front of the vehicle 100 at substantially equal intervals. The four front sonars 22F detect an obstacle in front of the vehicle 100. The vehicle 100 also includes four rear sonars 22R arranged at substantially equal intervals behind the vehicle 100. The four rear sonars 22R detect an obstacle behind the vehicle 100. The front sonar 22F and the rear sonar 22R detect obstacles in the forward and backward traveling directions, respectively.

Furthermore, the vehicle 100 includes one side sonar 22RF on the right front portion side of the vehicle 100. Side sonar 22RF detects an obstacle on the right side of vehicle 100 from the right front portion of vehicle 100. In addition, the vehicle 100 includes one side sonar 22LF on the left front side of the vehicle 100. Side sonar 22LF detects an obstacle on the left side of vehicle 100 from the left front portion of vehicle 100. The vehicle 100 includes one side sonar 22RR on the right rear side of the vehicle 100. Side sonar 22RR detects an obstacle on the right side of vehicle 100 from the right rear portion of vehicle 100. In addition, the vehicle 100 includes one side sonar 22LR on the left rear side of the vehicle 100. Side sonar 22LR detects an obstacle on the left side of vehicle 100 from the left rear portion of vehicle 100. Each of these side sonars 22RF, 22LF, 22RR, and 22LR detects an obstacle with which the vehicle 100 may be involved. In FIG. 1, a broken line S indicates a spatial range in which each sonar can detect an obstacle.
In addition, the number and installation position of each camera and each sonar described above are not limited to the above contents, and the number may be increased or decreased, or the arrangement position may be changed. However, it is desirable to select the number and arrangement position of the camera and the sonar so that the situation of the entire circumference of the vehicle 100 can be detected as much as possible. Moreover, you may make it detect the external condition of the vehicle 100 by sensors other than a camera and sonar.

Returning to FIG. 1, an inertial sensor 23 and a wheel speed sensor 24 are connected to the automatic parking control unit 1. Inertial sensor 23 is a sensor that detects the acceleration of vehicle 100. The wheel speed sensor 24 is a sensor that detects the wheel speed of each wheel of the vehicle 100.
An information output / input device 31 is connected to the automatic parking control unit 1. The information output / input device 31 includes a touch panel 32 and a speaker 33. The main body of the information output / input device 31 is arranged near the driver's seat so that the driver can operate the touch panel 32 and the like. The information output / input device 31 can display various information on the touch panel 32, output various sounds from the speaker 33, and accept various operations on the touch panel 32.

  That is, the information output / input device 31 can display car navigation information created based on a satellite positioning system or the like on the touch panel 32 and can output sound from the speaker 33. This information can include information received from a Vehicle Information and Communication System (VICS).

The information output / input device 31 can receive TV broadcasts and radio broadcasts, display images on the touch panel 32, and output sound from the speaker 33. Further, the information output / input device 31 includes an optical disc device (not shown), and can reproduce a CD (Compact Disc), a DVD (Digital Video (Versatile) Disk), a BD (Blu-ray Disc), and the like. . In addition, the information output / input device 31 includes an HDD (Hard Disk Drive) (not shown), and can also reproduce sound such as stored music.
Furthermore, various messages are notified from the vehicle 100 and the devices mounted on the vehicle 100 (such as an electronic toll collection system (ETC)), and various operations of the vehicle 100 and the devices mounted on the touch panel 32 are received. be able to.

  A brake system 41 is connected to the automatic parking control unit 1. The brake system 41 is a system that brakes the vehicle 100. The brake system 41 includes a brake device 42 that brakes the vehicle 100 and a brake control unit 43 that controls the brake device 42. The brake control unit 43 has the function of the auto brake hold control unit 44. The auto brake hold control unit 44 implements an automatic brake hold control unit. The brake device 42 generates hydraulic pressure (hydraulic pressure) and supplies hydraulic pressure to a wheel cylinder of each wheel (not shown) to generate a friction brake. The brake system 41 may use a regenerative brake when the vehicle 100 is a hybrid vehicle or the like. The brake device 42 is a device to which, for example, a brake by wire system is applied. Therefore, it is possible to generate a braking force regardless of the operation of a brake pedal (not shown). In some cases, the brake device 42 may be a system equipped with an electric brake booster. Even in this case, the braking force is generated by the electric brake booster regardless of the operation of the brake pedal (not shown). The brake control unit 43 is a control device that controls the brake device 42.

  The auto brake hold control unit 44 is a function provided in the brake control unit 43, and after the driver steps on the brake pedal (not shown), the brake state is maintained even if the driver removes his foot from the brake pedal. Control the brake hold function. The auto brake hold function cancels the auto brake hold state when a predetermined condition is satisfied, such as when an accelerator pedal (not shown) is operated. The auto brake hold state can be activated or canceled by operating a brake hold switch 45 installed in the vicinity of the driver's seat in the vehicle 100.

  A drive system 51 is connected to the automatic parking control unit 1. The drive system 51 is a system that causes the vehicle 100 to travel. In this example, the vehicle 100 is a hybrid vehicle, and includes an engine 52 and a motor / generator 53 as drive sources. The hybrid control unit 54 controls the engine 52 and the motor / generator 53 to cause the vehicle 100 to travel. Vehicle 100 is not limited to a hybrid vehicle. For example, in the case of a gasoline vehicle, only the engine 52 is used as a drive source. In the case of an electric vehicle including a fuel cell vehicle, only a motor is used as a drive source.

The transmission system 61 is a system that shifts the vehicle 100. The transmission system 61 includes a transmission 62 that changes the speed of the vehicle 100, a transmission control unit 63 that controls the transmission 62, and a shift lever 64 that is connected to the transmission 62. The transmission 62 may be an automatic transmission or a manual transmission. In this system, the transmission 62 can be shifted by the control of the transmission control unit 63 regardless of the operation of the driver. In this case, the transmission control unit 63 also variably operates the position of the shift lever 64 according to the speed change.
A boarding determination unit 65 is connected to the automatic parking control unit 1. The boarding determination unit 65 determines whether or not the driver is in the driver's seat.

An EPS (Electric Power-Steering) system 71 is connected to the automatic parking control unit 1. The EPS system 71 is a system that assists the driver's steering. The EPS system 71 includes a steering shaft 73 provided with a handle 72, a drive motor 74 that rotationally drives the steering shaft 73, and an EPS control unit 75 that controls the drive motor 74. The EPS system 71 assists an operation in which the steering shaft 73 is rotated using the drive motor 74 as a drive source, and the driver rotates the handle 72 to perform steering.
Next, the effect of the system centering on the automatic parking control unit 1 will be described.

Hereinafter, when “automatic parking operation” is described, a series of automatic parking control unit 1 controlling each system to automatically drive and drive vehicle 100 to automatically park in the flowcharts of FIGS. 4 and 5 to be described later. Shows the operation. In the case of “automatic parking function”, all the processes shown in the flowcharts of FIGS. 4 and 5 relating to automatic parking including “automatic parking operation” executed mainly by the automatic parking control unit 1 are shown.
The automatic parking control unit 1 controls automatic parking. Therefore, the camera group 21 and the sonar group 22 are used to detect a space for parking in a parking lot or the like. 3A to 3C are top views of the vehicle 100 for explaining a situation where the vehicle 100 searches for a space for parking.

  First, FIG. 3A is a top view showing a situation in which a space for parking in the parking lot 200 is mainly searched using the front camera 21F in the camera group 21. FIG. When the vehicle 100 enters the parking lot 200, a plurality of parking spaces 202 partitioned by white lines 201 are arranged on the left and right when viewed from the vehicle 100, and there is a parking space 202 in which another vehicle 203 is already parked. There is also a vacant parking space 202. The vehicle slows down in the direction of arrow 208 by the driver's driving.

  From the photographed image of the front camera 21F (FIG. 2), the region 211 can be recognized as a space that the vehicle 100 can use for parking. A brightness difference can be recognized by performing predetermined image processing on the image captured by the front camera 21F. Thereby, the vehicle 100 recognizes the area 211 that can be used for parking. The point where the camera recognition is good is the recognition of the white line 201. Camera recognition also has a space recognition function. What is not good at camera recognition is snow, white walls and other vehicles in the immediate vicinity. For this reason, it is difficult to perform brake control on obstacles necessary for automatic parking with only the captured image of the front camera 21F.

  Therefore, the sonar group 22 is also used. FIG. 3B is a top view showing a situation where a space for parking in the parking lot 200 is searched using all the sonars of the sonar group 22. Sonar can detect obstacles by transmitting and receiving sound waves, and is good at detecting the latest obstacles that the camera is not good at. Therefore, sonar is necessary to accurately perform the brake control for the obstacle. In addition, since the sonar has a higher space recognition function than the camera, the sonar group 22 is useful for guiding various parking patterns. FIG. 3B shows an area 221 that can be used for parking recognized by the sonar group 22.

  FIG. 3C is a top view showing the region 211 and the region 221 together. By using the front camera 21F and the sonar group 22 in combination, a wide space can be recognized as being usable for parking. It is also easy to handle brake control for obstacles. In the example of FIG. 3C, the parking space 202a is determined as a space for automatic parking. Further, a space in the right rear as viewed from the vehicle 100 is vacant, and this position is determined as a position where the vehicle 100 is turned back. Therefore, by the automatic parking control, the vehicle 100 is moved forward, the steering wheel is turned to the right, the vehicle is temporarily stopped at the turn-back position 222 (arrow 223), and the vehicle 100 is turned back into the parking space 202a (arrow 224). ) Is possible.

The above is the outline of automatic parking performed by using 21F and the sonar group 22 together, but the processing contents of automatic parking will be described in detail below.
4 and 5 are flowcharts for explaining processing executed by the automatic parking control unit 1. 6 to 9 are top views of the parking lot for explaining the processing executed by the automatic parking control unit 1. The flowchart shows an outline of a series of processes described below, and does not show the detailed processes executed by the automatic parking control unit 1. Processing not shown in the flowchart will be described as appropriate in the following description.

First, as shown in FIG. 6, the driver drives the vehicle 100 himself and enters the parking lot 200 as indicated by an arrow 208. At this time, the operation of the automatic parking function is performed by operating the touch panel 32 or the like (Yes in S1). The parking activation instruction detection unit 12 receives an operation instruction for the automatic parking function. Then, the parking activation instruction detection unit 12 displays a predetermined automatic parking function screen on the touch panel 32 (S2). Note that various types of automatic parking function screens are displayed as appropriate in a series of processes.
And the parking possible position detection part 11a of the automatic parking control part 11 uses the front camera 21F and the sonar group 22 together by the method as described above with reference to FIGS. 3A to 3C. And the parking possible position detection part 11a searches the parking space which can be used in order to park by this combined use (S3).

  In S3, the following processing is performed based on the search result. First, the parking position detection unit 11a detects a position where the vehicle 100 can be parked (parking space 202). In the example of FIG. 7, the parking spaces 202a and 202b are candidates for the target parking position. Moreover, the parking possible position detection part 11a calculates the path | route which avoids the obstruction when the vehicle 100 parks in parking space 202a, 202b based on the detection result of the front camera 21F and the sonar group 22. FIG.

  Next, the target parking position detection unit 11 b estimates the current position of the vehicle 100 based on the detection results of the inertial sensor 23 and the wheel speed sensor 24. And the target parking position detection part 11b calculates the target moving path | route of the vehicle 100 for parking in each parking space 202a, 202b on the basis of the position. And the target parking position detection part 11b displays the positional relationship of the vehicle 100 (own vehicle) and the parking spaces 202a and 202b on the touch panel 32 as shown in FIG. The parking spaces 202a and 202b are displayed and displayed with a mark such as being surrounded by a frame 205 in the image in an easy-to-understand manner for the driver.

After Yes in S1, the driver drives the vehicle 100 by himself and moves within the parking lot 200, but during that time, the process of S3 is performed (No in S4). When the driver operates a brake pedal (not shown) (Yes in S4) and stops the vehicle 100, the target parking position detection unit 11b performs the following process. That is, when the driver operates the touch panel 32 to select a target parking position (Yes in S5), the target parking position detection unit 11b determines the target parking position as the position. The selection can be made by touching the area indicated by the frame 205 or the like. When the selection is not made (No in S5), the process in S3 is continued. Note that the order of the processes of S4 and S5 may be reversed.
As described above, when the target parking position is determined (Yes in S5), the target parking position detection unit 11b shows an image on the touch panel 32 of the target parking position (in this example, the parking space 202a) as shown in FIG. A special mark 231 is displayed.

  Then, the brake holding instructing unit 13 instructs the auto brake hold control unit 44 to turn on the auto brake hold function (S6). The auto brake hold control unit 44 implements an automatic brake hold control unit. Thus, even when the driver removes his / her foot from a brake pedal (not shown), the braking state of the vehicle 100 is automatically maintained.

  Thereafter, the second parking operation interrupting unit 17 starts counting time (first time) with a timer (S7). And the automatic parking control part 11 displays the message of automatic parking on the touch panel 32, and alert | reports with an audio | voice message with the speaker 33 (S8). In this case, an automatic parking message may be displayed on the touch panel 32 only. The message to inform the driver here is "Auto brake hold turned on. To start automatic parking, press the brake hold switch, release your hand from the handle and release your foot from the brake pedal." It is the content of the purpose.

When the driver executes all the messages, the brake hold switch 45 is pressed to release the brake hold switch 45 (Yes in S9). The depression of the brake hold switch 45 in this case is an operation of the release instruction operation unit. When the brake hold switch 45 is not released (No in S9), the message is continuously displayed on the touch panel 32.
When a predetermined operation is performed during the series of processes (S2 to S8) described so far, the series of processes for automatic parking is stopped. For example, when the driver performs an operation of stopping the automatic parking function on the automatic parking function screen displayed on the touch panel 32, or when the driver performs an intentional operation of the shift lever 64. It is.

  When the brake hold switch 45 is released (Yes in S9), the process of S10 is executed. That is, the brake hold release instructing unit 15 instructs the auto brake hold control unit 44 to turn off the auto brake hold function (S10). Thus, the braking of the vehicle 100 is released. Further, the braking / holding continuation determination unit 14 stores the history of operating the auto brake hold function in S6 in a nonvolatile memory or the like (S10). Furthermore, the automatic parking control part 11 starts the operation | movement of automatic parking (it mentions later about the content of operation | movement) (S10). In addition, the second parking operation interruption unit 17 starts counting the elapsed time (second time) with a timer (S10). In addition, when there is no operation of a brake pedal (not shown), the automatic parking control part 11 controls as follows. That is, the parking control unit 11 does not shift to the automatic parking operation (S10) even if the brake hold switch 45 is released (S9). However, even in this case, the auto brake hold function (S6) itself remains ON.

  The automatic parking operation started by the automatic parking control unit 11 has the following contents. That is, as shown in FIG. 9, the automatic parking control unit 11 performs control so that the vehicle travels on the target movement route determined in S3. That is, the automatic parking control unit 11 controls the brake system 41, the drive system 51, the transmission system 61, and the EPS system 71. Thereby, the vehicle 100 parks in the parking space 202a used as a target parking position back.

That is, the automatic parking control unit 11 controls these systems, travels forward in the D range as indicated by an arrow 223, and stops once at the turn-back position 222. Next, the automatic parking control unit 11 travels back in the R range, causes the vehicle 100 to enter the parking space 202a that is the target parking position, and stops the vehicle 100.
Further, after starting the automatic parking operation (S10), it is determined whether or not there is an interruption condition for interrupting the automatic parking function during the automatic parking operation (S11).
That is, in S11, the operating condition is that the handle 72 is operated, the shift lever 64 is placed in the N range, and the like.

  Moreover, in S11, the 2nd parking operation | movement interruption part 17 judges whether the 1st time which started the count in S7 is more than predetermined time. The first time is the time from the determination of the target parking position (S5, S7) until the operation of releasing the automatic brake hold by the brake hold switch 45 is accepted (Yes in S9). The interruption condition is that the first time is equal to or longer than the predetermined time. Furthermore, in S11, the 2nd parking operation | movement interruption part 17 judges whether the 2nd time which started the count in S10 is more than predetermined time. The second time is the time from when the brake hold switch 45 is operated (Yes in S9) until the release of the operation of the brake pedal (not shown) is detected. The interruption condition is that the second time is equal to or longer than the predetermined time.

It is also an interruption condition that the driver determines that the driver does not exist in the driver's seat based on the determination by the boarding determination unit 65. The boarding determination unit 65 detects whether the driver is seated, a seating sensor that detects whether the driver is seated, an in-vehicle camera that images the interior of the vehicle (can determine whether the driver is seated by image processing), and detects whether the driver's seat is open or closed This can be realized by a door opening sensor or the like. In addition, various conditions that the automatic parking function should be interrupted can be used as the interrupt conditions.
When the automatic parking operation is terminated without the interruption condition (Yes in S12), the touch panel 32, the speaker 33, and the like are notified that the automatic parking operation is terminated. Then, the process proceeds to S13. If an interruption condition exists during the automatic parking operation (No in S12), the process proceeds to S16.

  In S13, the braking / holding continuation determining unit 14 determines whether or not the history of the operation of the autobrake hold is stored in S10. When the history is stored (Yes in S13), the brake system 41 is controlled again to turn on the auto brake hold function, and the process proceeds to S15. Therefore, the vehicle 100 is braked and stopped even if the driver does not depress a brake pedal (not shown). When the history is not stored (No in S13), the process proceeds to S15. In this case, the auto brake hold function remains OFF. The case where the history of the operation of the auto brake hold is not stored in S10 is the following case. That is, even if the auto brake hold function is turned on in S6, the driver operates the brake hold switch 45 to intentionally turn off the function. In S15, the automatic parking control unit 11 controls the shift lever 64 to enter the P range, and the automatic parking is finished.

  On the other hand, in S16, since there is an automatic parking cancellation condition (Yes in S11), the automatic parking function is canceled. And it is judged whether the restart conditions of an automatic parking function exist (S17). As the restart condition, a predetermined condition is satisfied. An example of the predetermined condition is that a predetermined operation has been performed on a selection screen 81 that is a type of the automatic parking function screen shown in FIG. On the selection screen 81, a resume button 82 and a cancel button 83 are displayed. Here, the restart condition is that the driver operates the restart button 82. When the cancel button 83 is operated, canceling the automatic parking function is selected.

  When the restart condition exists (Yes in S17), the process returns to S2 and the automatic parking function is restarted. When a certain period of time has elapsed without the restart condition (No in S17, Yes in S18), the cancellation of the automatic parking function is confirmed (S19), and the series of processes ends. If a certain period of time has not elapsed without a restart condition (No in S17, No in S18), the process returns to S16. When the cancel button 83 is operated, the automatic parking function may be canceled without waiting for a certain period of time (Yes in S18).

  In addition, when it corresponds to the said interruption conditions (Yes of S11), an automatic parking function can be restarted from S2 by satisfy | filling the said restart conditions (Yes of S17). On the other hand, when the stop condition is satisfied during a series of operations of the automatic parking function, the processing itself of FIGS. 4 and 5 is stopped and the processing is not resumed. When resuming, the process is restarted from S1. This “cancellation condition” includes, for example, that the shift lever 64 is in the P range, the electric parking brake is activated, the touch panel 32 and the like are operated during a series of operations of the automatic parking function. For example, an operation instruction for the automatic parking function is given. Furthermore, when the stop condition is satisfied during a series of operations of the automatic parking function, the series of operations of the automatic parking function stops, but in this case, if the stop condition is canceled, the automatic parking function is started from the point of stop. Restart the series of operations. Examples of the “stop condition” include operation of a brake pedal (not shown).

Next, actual operation of automatic parking will be described based on a specific situation of automatic parking.
FIG. 11A to FIG. 11H are top views of a parking lot for explaining the case where a shift operation is performed during the operation of the automatic parking function over time. First, as shown in FIG. 11A, the vehicle 100 enters the parking lot 200 by the driver's driving (in the direction of the arrow 208), and operates the touch panel 32 or the like to give an instruction to start the automatic parking function. Accordingly, the target parking position detection unit 11b displays an image of the parking space 202a on the screen of the touch panel 32 as a candidate for the target parking position, as shown in FIG. 11B. That is, an image as shown in FIG. 11B is displayed on the touch panel 32. As described above, a plurality of candidates may be displayed. As shown in FIG. 11C, another vehicle 203a comes out from the parking space 202 on the right front as viewed from the vehicle 100 at this timing. Since the vehicle 203a is in the way of getting out of the parking lot, the driver of the vehicle 100 puts the shift lever 64 from the D range to the R range in order to move the vehicle backward. As a result, the automatic parking function is stopped, and the driver retreats the vehicle 100 as indicated by the arrow 208 by his / her own driving. In this case, as shown in FIG. 11D, after passing the vehicle 203a, the operation of the automatic parking function can be instructed again by operating the touch panel 32 or the like.

  In another example, the parking space 202a is selected as the target parking position by operating the touch panel 32 as shown in FIG. 11E from the situation of FIG. 11B. Thereby, an image as shown in FIG. 11E in which the mark 231 is displayed in the parking space 202a is displayed on the touch panel 32. At this timing, another vehicle 203 a comes out of the parking space 202 from the right front as viewed from the vehicle 100. In order to prevent the vehicle 203a from leaving the parking lot, the driver of the vehicle 100 moves the shift lever 64 from the D range to the R range in order to move the vehicle backward. As a result, the automatic parking function is canceled as shown in FIG. 11G, and a message “The determined parking position has been released. A similar message is emitted. Then, as shown in FIG. 11H, the driver operates the vehicle 100 by himself and moves the vehicle 100 backward as indicated by an arrow 208.

  FIG. 12A to FIG. 12E are top views of a parking lot for explaining another example when a shift operation is performed during the operation of the automatic parking function over time. First, as shown in FIG. 12A, the vehicle 100 enters the parking lot 200 by the driver's driving (in the direction of the arrow 208), and operates the touch panel 32 or the like to give an operation instruction for the automatic parking function. As a result, as shown in FIG. 12B, an image is displayed on the screen of the touch panel 32 that the parking space 202a is appropriate as a target parking position candidate. That is, an image as shown in FIG. 12B is displayed on the touch panel 32. As described above, a plurality of candidates may be displayed. Then, the driver operates the touch panel 32 to determine the parking space 202a as the target parking position. Then, an image as shown in FIG. 12C is displayed, and a mark 231 is displayed in the parking space 202a. This indicates that the parking space 202a has been determined as the target parking position. Then, the driver operates the brake hold switch 45 in order to shift to the actual automatic parking operation. Then, the auto brake hold function is turned on, and the driver releases his limbs from the brake pedal (not shown), the accelerator pedal (not shown), the handle 72, and the shift lever 64. Then, as shown in FIG. 12D, the arrow 223 is moved forward, the vehicle is temporarily stopped at the turn-back position 222, the arrow 224 is moved backward, and the vehicle is parked in the parking space 202a in the back.

  However, in the meantime, as shown in FIG. 12E, the other vehicle 203a may come out from the parking space 202 on the right front side, and the vehicle 100 may interfere with the progress of the other vehicle 203a. Therefore, the driver of the vehicle 100 changes the position of the shift lever 64 from the D range to the R range. As a result, the automatic parking function is stopped, and a selection screen 81 shown in FIG. If the cancel button 83 is selected on this screen, the driver drives by himself to retreat the vehicle 100 and overtake the other vehicle 203a. Then, the operation of the automatic parking function is performed again by operating the touch panel 32 and the like, and automatic parking is performed again. When the resume button 82 is operated, the automatic parking function is resumed from S2.

  According to the automatic parking control unit 1 described above, after the automatic parking function is activated (after Yes of S1), the following control is performed before the parking operation to the target parking position is started. That is, when a brake pedal (not shown) is operated (Yes in S4), the automatic parking control unit 1 turns on the auto brake hold function (S6). Therefore, even if the driver removes his / her foot from a brake pedal (not shown), the braking force is functioning, so that the vehicle 100 does not move carelessly.

  When the brake hold switch 45 is operated to release the auto brake hold function (Yes in S9), the automatic parking control unit 1 performs the following control. That is, the automatic parking control unit 1 turns off the automatic brake hold function turned on in S6 and starts an automatic parking operation (S10). That is, the vehicle 100 actually moves in an automatic operation and the automatic parking operation starts. That is, the switch for instructing the start of the automatic parking operation and the brake hold switch 45 are shared. Therefore, a dedicated switch for instructing the start of the automatic parking operation is not necessary. Therefore, the layout of various operation buttons can be improved. The automatic parking control unit 1 can perform control that matches the driver's intention of turning off the automatic brake hold function and starting the automatic parking operation. Further, the braking by the auto brake hold function can be released without limiting the way of starting the automatic parking operation.

  The automatic parking control unit 1 requires the following conditions to turn on the automatic brake hold function (S6). That is, a parking space that can be parked is detected (S3), and the driver determines the target parking position (Yes in S5). That is, before the driver determines the target parking position, the vehicle 100 can be moved by the driving of the driver. Then, after the driver determines the target parking position (Yes in S5), the vehicle 100 can be prevented from moving unnecessarily.

  The automatic parking control unit 1 performs the following control when the automatic brake hold function is ON (S6) and the automatic parking operation is completed (Yes in S12). That is, in this case, the history of the operation of the auto brake hold remains (Yes in S10 and S13). Therefore, after completing the automatic parking operation (Yes in S12), the automatic parking control unit 1 turns on the auto brake hold function (S14). That is, when automatic parking starts with auto brake hold, it ends with auto brake hold. Thereby, after the operation of automatic parking is completed (Yes in S12), the vehicle 100 does not move carelessly. On the other hand, even if the auto brake hold function is turned on (S6), the driver may operate the brake hold switch 45 to turn off the auto brake hold function. In this case, in accordance with the driver's intention, after the automatic parking operation is completed (Yes in S12), the auto brake hold function is kept OFF (No in S13).

  Further, when the driver is operating a brake pedal (not shown) (S4), when the brake hold switch 45 is released (Yes in S9), the following is performed. That is, in this case, the automatic parking control unit 1 turns off the automatic brake hold function, releases the braking (S10), and starts the automatic parking operation (S10). Therefore, from the state in which the driver is operating the brake pedal (S4), by releasing the braking and starting the automatic parking operation (S10), it is possible to give the driver a sense of security.

  Further, the automatic parking control unit 1 sets the operation of the shift lever 64, the handle 72, or the brake pedal (not shown) as a stop condition (S11). If this stop condition is satisfied, the automatic parking control unit 1 stops the automatic parking operation (S16). Thereby, the driver's intention to stop the operation can be given priority over the continuation of the automatic parking operation. This point is as described above with reference to FIGS. 11A to 11H and FIGS. 12A to 12E.

  Furthermore, the stop time (S11) is that the first time or the second time is equal to or longer than a predetermined time. The first time is the time from the determination of the target parking position (Yes in S5, S7) to the operation of the brake hold switch 45 (Yes in S9). The second time is the time from the operation of the brake hold switch 45 (Yes in S9) to the release of the operation of the brake pedal (not shown) (S10). When these times are longer than a predetermined time, in the above example, there is a high possibility that the other vehicle 203 enters and leaves each parking space 202. In other words, it is possible to prevent the automatic parking operation from being performed in a situation where the situation may have changed from the time of searching for the parking space (S3).

  Further, when the automatic parking operation is stopped (S16), a resumption condition (S17) is set. As the restart condition, the brake hold switch 45 is operated or a predetermined condition is satisfied. As a predetermined condition, it is mentioned that the restart switch 82 was operated in the selection screen 81 which is a kind of the automatic parking function screen shown in FIG. Therefore, the automatic parking control unit 1 can restart the automatic parking function not only by operating the brake hold switch 45 but also by operating the restart switch 82 or the like.

  The control contents of a series of automatic parking functions by the automatic parking control unit 1 have been described above. Note that further detailed contents such as basic parking space search, target route calculation, vehicle control in automatic parking execution, and the like are known in Patent Documents 1 and 2 described above.

  Needless to say, the present invention is not limited to the description of the above-described embodiment. For example, in the above-described example, the operation of automatic parking has been described as an example of parking by warehousing from the back side, but automatic parking by warehousing from the front side of the vehicle 100 may be performed. Alternatively, the driver may be able to select whether the goods are received from the back side or the front side.

1 Automatic parking control unit (parking support device)
DESCRIPTION OF SYMBOLS 11 Automatic parking control part 11a Parking possible position detection part 11b Target parking position detection part 12 Parking starting instruction | indication detection part 13 Braking holding | maintenance instruction | indication part 14 Brake | holding holding | maintenance continuation determination part 15 Brake | holding hold cancellation | release instruction | indication part 16 1st parking operation interruption part 17 2nd Parking operation interruption unit 18 Restart instruction unit 44 Auto brake hold control unit (automatic brake holding control unit)
45 Brake hold switch (release instruction operation part)
64 Shift lever 72 Handle 82 Resume switch (Resume instruction receiving part)
100 Vehicle 202a Target parking position

Claims (6)

An automatic parking control unit for performing a parking operation of the vehicle at the target parking position determined by a predetermined means;
A parking activation instruction detection unit that receives an activation instruction of the parking operation by the operation of the automatic parking control unit;
When the vehicle stops between the reception of the activation instruction and the start of the parking operation by the operation of the automatic parking control unit, the brake holding control unit performs braking holding on the automatic braking holding control unit that performs braking holding of the vehicle. A parking support apparatus comprising: a brake holding instruction unit that instructs execution. The automatic parking control unit
A parking position detection unit for detecting a position where the vehicle can be parked;
A target parking position determination unit that determines the target parking position based on the parking position detected by the parking position detection unit;
The brake holding instruction unit, when the target parking position is determined by the target parking position determination unit, instructs the automatic braking holding control unit to execute the braking holding. Parking assistance device.   When the parking operation of the vehicle at the target parking position is completed by the automatic parking control unit, depending on whether or not the vehicle has been braked and held by the automatic braking and holding control unit immediately before the start of the parking operation activation instruction. The parking support device according to claim 2, further comprising a braking / holding continuation determination unit that determines whether or not to continue the braking / holding.   The said automatic parking control part starts the said parking operation, when the cancellation | release instruction | indication operation part which receives the operation | movement of cancellation | release of the braking holding in the said vehicle performed by the said automatic braking holding | maintenance control part is operated. The parking assistance device according to any one of claims 3 to 4.   5. The brake holding release instructing unit that instructs the automatic braking holding control unit to release the brake holding when the parking operation is started by the automatic parking control unit. The parking assistance device described. An automatic parking control unit for performing a parking operation of the vehicle at the target parking position determined by a predetermined means;
A parking activation instruction detection unit that receives an activation instruction of the parking operation by the operation of the automatic parking control unit;
An automatic braking and holding control unit that holds and holds the vehicle when the vehicle is stopped between the reception of the activation instruction and the start of the parking operation by the operation of the automatic parking control unit;
A vehicle capable of automatic parking, comprising: a braking holding instruction unit that instructs the automatic braking holding control unit to execute the braking holding.

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