JP2005041433A - Vehicle guiding device and route judging program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To strictly guide a vehicle in accordance with a set moving route in a vehicle guiding device for use in guiding a vehicle from a present position of the vehicle to its target stopping position. <P>SOLUTION: A movable range of a vehicle to be guided is set (S300) in response to pre-stored vehicle information, a driver visually recognizing an image around the vehicle inputs a moving route up to a target stopping position (S310: YES), the judgment on whether or not the moving route is in the movable range of the vehicle is made, and when the judgment that the vehicle is in the movable range is made (S320: YES), the moving route is stored in RAM (S330). In addition, when the inputted moving route is in an allowable range (S350: YES) even if the judgment that the moving route inputted by the driver is out of the movable range of the vehicle is made(S320: NO), the moving route is corrected to such a range as one in which the vehicle can move and then the corrected moving route is stored in RAM (S360). Then, the vehicle is guided along with the moving route. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a vehicle guidance device that guides a vehicle to a target stop position.

2. Description of the Related Art Conventionally, a vehicle guidance device has been known that enables a parking operation to be performed easily even by a driver with a low driving skill level (see, for example, Patent Document 1).
In this vehicle guidance device, when a driver operates a touch panel display on which a landscape behind the vehicle is displayed and sets a movement route from the current location of the vehicle to a target stop position, the vehicle follows the movement route set by the vehicle guidance device. The steering load is controlled so that the vehicle is easy to move so that the vehicle does not deviate from the target movement path.
JP 2002-362271 A

  However, in the above vehicle guidance device, even if a travel route from the current location of the vehicle to the target stop position is set, turning performance such as a minimum turning radius differs depending on the vehicle. There was a problem that the vehicle could not move.

  In view of such problems, an object of the present invention is to guide a vehicle along a set movement route in a vehicle guidance device that guides the vehicle from the current location of the vehicle to a target stop position.

  In the vehicle guidance device according to claim 1, which is made to achieve the above object, a driver who has visually recognized an image around the vehicle displayed on the display unit displays a movement route of the vehicle to the target stop position. When the route is input using the route input means, the route determination means determines whether or not the vehicle can move along the movement route based on the vehicle information stored in the vehicle information storage means, and the vehicle becomes the movement route. When it is possible to move along, the storage of the movement route by the route storage means is permitted. Then, the guidance control means guides the vehicle to the target stop position according to the movement route stored in the route storage means.

  That is, even if the guidance control means tries to guide the vehicle to the target stop position according to the movement route input by the driver via the route input means, the vehicle to be guided may not move depending on the movement route. The route determination means in the present invention determines whether or not the vehicle can move along the movement route based on the vehicle information stored in the vehicle information storage means, and the vehicle can move along the movement route. Sometimes, the storage of the movement route by the route storage means is permitted.

  Therefore, in such a vehicle guidance device (Claim 1), the movement route stored in the route storage means is always a route on which the vehicle can move, and therefore the vehicle is guided along the set movement route. Can do.

  By the way, as the vehicle information stored in the vehicle information storage means, it is only necessary to know the minimum turning radius of the vehicle. As described in claim 2, at least the wheelbase length and the maximum steering angle are stored. Is preferred.

With such a vehicle guidance device (claim 2), it is possible to calculate a path along which the vehicle can move more accurately from the wheelbase length and the maximum steering angle.
Further, for example, the guidance control means may be configured to control only the steering load in the steering device and assist the driver in maneuvering the vehicle. The control amount calculation means calculates the control amounts of the driving device (accelerator), the braking device (brake), and the steering device (steering) based on the movement route stored in the route storage means, and based on the calculation result Desirably, the autopilot means is configured to autopilot the vehicle.

  With such a vehicle guidance device (Claim 3), when the vehicle is moving, the driver does not need to perform an operation on the vehicle, so the driver concentrates only on safety confirmation around the vehicle. be able to.

Furthermore, in the vehicle guidance device according to claim 3, as described in claim 4, the display means and the route input means are preferably configured separately from the vehicle.
With such a vehicle guidance device (claim 4), the display means and the route input means can be configured as a terminal device separated from the vehicle, so that the driver can remotely operate the vehicle without getting into the vehicle. can do.

  By the way, for example, when the vehicle information storage means is configured to be separated from the vehicle, vehicle information about many vehicles (vehicle types) is used when a plurality of vehicles are to be guided using the display means and the route determination means. Can be stored in the vehicle information storage means, and the vehicle information to be used can be selected from a lot of vehicle information. However, in this case, the vehicle information to be stored in the information storage means differs depending on the model, grade, etc. of the vehicle even in the same vehicle type, so the vehicle information to be stored in the vehicle information storage means The amount of information becomes enormous.

Therefore, in order to solve this problem, as described in claim 5, the vehicle information storage means may be mounted on the vehicle.
That is, for each guided vehicle, a vehicle information storage unit that stores vehicle information corresponding to only the vehicle is mounted.

  Therefore, with such a vehicle guidance device (claim 5), a plurality of vehicles can be guided using the display means and the route determination means without storing a huge amount of vehicle information in the vehicle information storage means. Can do.

  Further, in the vehicle guidance device according to any one of claims 3 to 5, as described in claim 6, according to a command from the outside, the automatic steering of the vehicle performed by the automatic piloting means is stopped, and the vehicle is It is desirable to have vehicle stopping means for stopping.

  With such a vehicle guidance device (Claim 6), the vehicle can be stopped when an obstacle such as a pedestrian or another vehicle appears on the movement route, so that an accident can be prevented. it can.

  Further, in the vehicle guidance device according to any one of claims 1 to 6, the image pickup means is provided in the vehicle, for example, picks up a scene in the traveling direction of the vehicle and displays the image on the display means. However, as described in claim 7, the imaging unit images the vehicle from above the vehicle, and the image captured by the imaging unit is wirelessly transmitted to the display unit and displayed. It is preferable to be configured as described above.

  In such a vehicle guidance device (Claim 7), since the image around the vehicle is imaged from the vehicle information, the captured image displayed on the display means is less distorted. The visibility at the time can be improved.

  Furthermore, in the vehicle guidance device according to any one of claims 1 to 7, when the driver inputs a movement route, the driver uses, for example, route input means including a keyboard to set the movement route. However, as described in claim 8, the display unit and the route input unit include a touch panel type display, and the driver touches the touch panel type display on which an image is displayed. It is desirable to configure to input a movement route.

With such a vehicle guidance device (claim 8), the driver can input the movement route on the screen on which the image is displayed, and therefore can easily input the movement route.
In the vehicle guidance device according to any one of claims 1 to 8, when the route determination unit determines that the vehicle cannot move along the movement route input via the route input unit, for example, The driver may be configured to re-input the travel route. However, as described in claim 9, the input travel route is corrected to a range in which the vehicle can move, and the travel route of the travel route by the route storage unit is corrected. It is desirable to allow memory.

  With such a vehicle guidance device (claim 9), it is possible to prevent the driver from re-inputting the input route over and over, so the travel route input time by the driver can be shortened.

  Furthermore, in the vehicle guidance device according to any one of claims 1 to 9, when the movement route is stored in the route storage unit as described in claim 10, the movement route stored by the route storage unit is displayed. It is preferable to provide route display means for displaying on the display means.

  With such a vehicle guidance device (Claim 10), the driver can check the movement route set before the vehicle is guided, and thus the vehicle is prevented from moving based on the erroneously inputted movement route. be able to.

  Next, a route determination program according to claim 11 realizes a function as route determination means in the vehicle guidance device according to any one of claims 1 to 10 by computer processing.

  If such a route determination program (Claim 11) is used so that the driver inputs the travel route, it is instantaneously determined whether or not the travel route input by the driver is within a movable range of the vehicle. Since the movement route can be stored while making the determination, the time for inputting the movement route can be shortened.

Embodiments according to the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing a schematic configuration of a vehicle guidance device 1 to which the present invention is applied.
As shown in FIG. 1A, the vehicle guidance device 1 is composed of devices distributed in three places, a parking lot 2, a vehicle 3, and a mobile terminal 4, and each device is configured to be able to transmit and receive data wirelessly. ing.

  In the parking lot 2, a camera 21 (imaging means in the present invention) installed so as to look down on the entire parking lot 2 from above the parking lot 2 and an antenna 22 for transmitting and receiving data to and from the portable terminal 4. And an imaging control device 23 that performs control such as transmission of image data captured by the camera 21 and the camera 21.

  Information indicating the orientation and position of the camera 21 is stored in the imaging control device 23. When a signal requesting parking lot information is received from the terminal control device 43 of the portable terminal 4 described later, via the antenna 22, An image captured by the camera 21 and information indicating the orientation and position of the camera 21 are transmitted.

  The vehicle 3 includes an antenna 31 for transmitting / receiving data to / from the mobile terminal 4, a vehicle guidance ECU 32 (ECU is an electronic control device) for controlling vehicle guidance, and a GPS receiver 33 (GPS is global). An abbreviation of Positioning System), and a steering wheel 35, an accelerator 36, and a brake 37 controlled by the vehicle guidance ECU 32 via the gateway 34.

  As shown in FIG. 1B, the vehicle guidance ECU 32 (guidance control means and automatic steering means in the present invention) includes a CPU 32A, ROM 32B (vehicle information storage means in the present invention), and RAM 32C. When receiving a command from the portable terminal 4, the CPU 32A calculates the control amounts of the steering 35, the accelerator 36, and the brake 37 according to the control program stored in the ROM 32B, and based on the calculation result, the steering 35 In addition to controlling the accelerator 36 and the brake 37, transmission / reception of data to / from the portable terminal 4 is controlled.

  In addition to the control program, the ROM 32B stores vehicle information that is vehicle-specific information (vehicle length, vehicle width, wheelbase length, maximum steering angle, wheel position, etc.). The RAM 32C stores data transmitted from the portable terminal 4 and functions as a work area for the CPU 32A.

  Further, the CPU 32 </ b> A is configured to transmit the vehicle information to the terminal control device 43 via the antenna 31 when receiving a signal requesting vehicle information from the terminal control device 43 of the portable terminal 4 described later. At this time, the CPU 32A receives the current location information of the vehicle 3 detected by the GPS receiver 33 from the GPS receiver 33, and uses the current location information of the vehicle 3 as vehicle information combined with vehicle-specific information as a terminal control device. 43.

  Next, as shown in FIG. 1A, the mobile terminal 4 includes an antenna 41 for transmitting and receiving data to and from the imaging control device 23 of the parking lot 2 and the vehicle guidance ECU 32 of the vehicle 3, and a touch panel type. A display 42, a terminal control device 43, a button operation unit 44, and a speaker 45 are provided.

  The touch panel display 42 includes a display unit 42B (display unit in the present invention) and an operation input unit 42A (route input unit in the present invention) including a sensor that detects that the display unit 42B is touched. A person (driver) using the vehicle guidance device 1 operates the operation input unit 42A and inputs a command for guiding the vehicle 3 by touching the display unit 42B while viewing the display unit 42B. .

  Further, the button operation unit 44 is disposed outside the display unit 42B (see FIG. 4), and the driver operates the button operation unit 44 to determine the movement route or the determined movement route. Information is transmitted to the vehicle 3.

  Similarly to the vehicle guidance ECU 32, the terminal control device 43 includes a CPU 43A, a ROM 43B, and a RAM 43C (route storage means in the present invention). The CPU 43A controls transmission / reception of data between the terminal control device 43, the imaging control device 23, and the vehicle guidance ECU 32, and the received data, the operation of the touch panel display 42 and the button operation unit 44 by the driver, and the ROM 43B. Based on the stored control program (including the route determination program referred to in the present invention), image processing is performed, and control is performed to display the image after image processing on the display unit 42B.

  A procedure for guiding the vehicle 3 to a position desired by the driver (target stop position) using the vehicle guidance device 1 configured as described above will be described with reference to FIG. FIG. 2 is a flowchart showing a vehicle guidance process executed by the terminal control device 43.

In the vehicle guidance process, the data stored in the RAM 43C is temporarily deleted in S100, and the process proceeds to S110.
Thereafter, the screen display process (S110), the route determination process (S130), the route analysis process (S150), and the vehicle operation process (S160) are sequentially executed, and the vehicle guidance process ends. When the screen display process and the route determination process are finished, it is determined whether or not an error is displayed on the display unit 42B (S120, S140). If it is determined that an error is displayed (S120, S140: YES) ), The vehicle guidance process is terminated at that time. If it is determined that no error is displayed (S120, S140: NO), the process proceeds to the next process.

Next, the screen display process in S110 of FIG. 2 will be described in detail with reference to FIG. FIG. 3 is a flowchart showing screen display processing performed by the terminal control device 43.
In the screen display process shown in FIG. 3, in S200, vehicle information that is information such as the wheelbase length, the maximum steering angle, and the current location of the vehicle 3 is requested to the vehicle guidance ECU 32, and the process proceeds to S210.

  In S210, it is determined whether or not the vehicle information from the vehicle 3 has been received. If it is determined that the vehicle information from the vehicle 3 has been received, the process proceeds to S220. If it is determined that the vehicle information from the vehicle 3 has not been received, the process proceeds to S215.

  In S215, it is determined whether or not a certain time has elapsed since the vehicle information is requested to the vehicle guidance ECU 32 in S200. If it is determined that the certain time has elapsed, the process proceeds to S236, and the certain time has elapsed. If it is determined that it is not, the process returns to S210.

  Next, in S220, the image pickup control device 23 of the parking lot 2 is requested for the parking lot information including the captured image from the camera 21 installed in the parking lot 2, the orientation of the camera 21, and the position information. The process proceeds to S230.

  In S230, it is determined whether or not parking lot information has been received from the imaging control device 23. If it is determined that parking lot information has been received, the process proceeds to S240, and if it is determined that parking lot information has not been received, S235 is determined. Migrate to

  In S235, as in S215, it is determined whether or not a certain period of time has elapsed since reception of parking lot information to the imaging control device 23 in S220. If it is determined that a certain period of time has elapsed, the process proceeds to S236. If it is determined that the predetermined time has not elapsed, the process returns to S230.

In S236, which is shifted to when it is determined in S215 and S235 that the fixed time has elapsed, an error is displayed on the display unit 42B, and the screen display process is terminated.
The fixed time in S215 and S235 is a time required to determine whether or not the imaging control device 23 of the parking lot 2 and the vehicle guidance ECU 32 of the vehicle 3 are operating normally, and the set time May be set to about 3 seconds, for example.

  On the other hand, in S240, the vehicle position is determined based on the parking lot information from the imaging control device 23 and the vehicle information from the vehicle guidance ECU 32. That is, here, well-known image processing is performed from the image captured by the camera 21, the positions of the own vehicle (vehicle 3) and other vehicles are determined in the captured image, and further, information on the orientation and position of the camera 21 and Based on the current location information of the vehicle 3 detected by the GPS receiver 33, it is determined which of the vehicles in the captured image is the own vehicle (the vehicle 3).

Next, the process proceeds to S250. In S250, the vehicle 3 is cut out from the captured image by image processing, converted to another layer, and the process proceeds to S260.
In S260, even if the region where the vehicle 3 is present in the captured image is supplemented with the surrounding color (in this embodiment, the color of the asphalt) and the vehicle 3 is moved on the display unit 42B, the vehicle 3 moves. Make sure that the previous color is not lost.

  Next, the process proceeds to S270. In S270, the captured image after the image processing in S260 and the vehicle 3 converted into another layer in S250 are stored in the RAM 43C of the terminal control device 43 as an initial image.

Then, the process proceeds to S280, and in S280, the vehicle 3 converted into another layer is superimposed on the captured image after the image processing and displayed on the display unit 42B, and the screen display process is ended.
By the way, when the mobile terminal 4 is turned on and the screen display process is executed, a screen as shown in FIG. 4 is displayed on the display unit 42B of the mobile terminal 4, for example. FIG. 4 is an explanatory diagram showing a display example of the initial screen.

As shown in FIG. 4, a touch panel display 42 and a button operation unit 44 are provided on the surface of the portable terminal 4.
Moreover, the captured image from the sky of the parking lot 2 by the camera 21 is displayed on the display unit 42B of the touch panel display 42, and the vehicle 3 is displayed in the captured image. The vehicle 3 is displayed so as to be movable on the display unit 42B when the driver touches the display unit 42B, and a travel route described later can be input.

  Next, a process for inputting a movement route using the portable terminal 4 will be described with reference to FIG. FIG. 5 is a flowchart showing a route determination process (S130 in FIG. 2) executed by the terminal control device 43 in response to the movement route input operation performed by the driver. The route determination process corresponds to the route determination means and the route determination program referred to in the present invention. Further, the processing shown in S390 in the route determination processing corresponds to the route display means in the present invention.

Here, the procedure for the driver to input the movement route and the allowable range in S350 will be described in detail later, and the description thereof will be omitted.
In the route determination process of FIG. 5, in S300, the movable range of the vehicle 3 is set on the display unit 42B based on the vehicle information transmitted from the vehicle guidance ECU 32 of the vehicle 3. Specifically, an area through which the front and rear wheels of the vehicle 3 can pass is calculated from the vehicle length, the wheel base length, the maximum steering angle, and the wheel position, and based on this area, the movable range from the entire captured image is calculated. Set.

  That is, in the vehicle guidance device 1 of the present embodiment, the minimum turning radius of the vehicle 3 is set by setting the movable range of the vehicle 3 in consideration of the wheel positions of the front wheels and the rear wheels (in short, the inner wheel difference and the outer wheel difference). Compared with the case where the movable range of the vehicle 3 is set only from the above, the accuracy when inputting the movement route is improved.

  Next, in S <b> 310, it is determined whether the driver has operated the touch panel display 42 and has input the movement route of the vehicle 3. If it is determined that the driver has input the travel route of the vehicle 3, the process proceeds to S320, and if it is determined that the driver has not input the travel route of the vehicle 3, the process proceeds to S315.

  In S315, it is determined whether or not a fixed time has elapsed since the RAM 43C was cleared or written. If it is determined that the predetermined time has elapsed, the process proceeds to S316, a display indicating an error is displayed on the display unit 42B, the movement path stored in the RAM 43C is cleared in S317, and the path determination process is terminated.

If it is determined in S315 that a certain time has not elapsed since the RAM 43C was cleared or written, the process proceeds to S380.
Note that the fixed time in the process in S315 is to determine whether or not the driver who performs the operation of inputting the moving route has an intention to continue to input the moving route, and is set to about 10 seconds, for example. You just have to.

  In S320, which is shifted when it is determined in S310 that the driver has input the travel route of the vehicle 3, the travel route input by the driver is within a movable range for the vehicle 3 with reference to the vehicle information. Determine whether or not. If it is determined that the vehicle 3 is within the movable range, the process proceeds to S330, the movement route is stored in the RAM 43C, and an image obtained by moving the vehicle 3 according to the movement route is displayed on the display unit 42B in S340. Migrate to

If it is determined in S320 that the travel route input by the driver is not within the movable range for the vehicle 3, the process proceeds to S350, and it is determined whether or not the travel route is within the allowable range.
If it is determined in S350 that the movement route input by the driver is within the allowable range, the process proceeds to S360, and the movable range within the shortest distance from the movement route input by the driver is stored in the RAM 43C as a new movement route. In S370, an image obtained by moving the vehicle 3 according to the new movement route is displayed on the display unit 42B, and the process proceeds to S380.

  In S350, if it is determined that the travel route input by the driver is outside the allowable range, the process proceeds to S365, and the vehicle 3 cannot move on the display unit 42B, for example, "Cannot move." In addition, a warning sound is generated from the speaker 45, and the process proceeds to S385.

  Next, in S380, it is determined whether or not the driver has pressed the “Determine” or “Clear” button in the button operation unit 44. If it is determined that the driver has pressed the “OK” button, the process proceeds to S390. If it is determined that the driver has pressed the “clear” button, the process proceeds to S385. Alternatively, if it is determined that the driver has not pressed any button, the process returns to S300 and the route determination process is repeated.

  In S385, the movement path stored in the RAM 43C is cleared, and in S386, the initial image stored in the RAM 43C is displayed. The process returns to S300, and the path determination process is repeated.

Moreover, in S390, the moving path memorize | stored in RAM43C is displayed as a moving image which the vehicle 3 moves on the display part 42B, and it transfers to S400.
In S <b> 400, it is determined again whether or not the driver has pressed the “decision” or “clear” button in the button operation unit 44. If it is determined that the driver has not pressed any button, the process returns to S390 and the travel route is displayed again. If it is determined that the driver has pressed the “clear” button, the process proceeds to S385. Alternatively, if it is determined that the driver has pressed the “decision” button, the route determination process is terminated.

In this way, the route determination process is executed.
By the way, as shown in FIG. 6, the procedure when the driver inputs the movement route of the vehicle 3 is to touch the host vehicle (vehicle 3) on the display unit 42B with a finger and move to the target stop position in this state. If the target stop position is reached, the finger may be released from the display unit 42B. That is, if the finger is moved from the position A shown in FIG. 6 to the position B as shown by the arrow, the route determination process shown in FIG. 5 is repeatedly executed in the process, and the vehicle moves with the movement of the finger. 3 moves on the display unit 42B, and the movement path is stored in the RAM 43C.

  Note that when inputting the movement route, the driver does not always set the movement route within a range in which the vehicle 3 can move. For this reason, in the vehicle guidance device 1 of the present embodiment, as shown in FIG. 7A, when the driver tries to move the vehicle 3 from the position C to the position D, the vehicle 3 can move. Even if the driver tries to set a movement route as indicated by the broken line outside the range, the movement route is set as indicated by the solid line within the range in which the vehicle 3 can actually move. It is configured.

  However, as in the case where the vehicle 3 is to be moved from the position E to the position F as shown in FIG. If it is clearly deviated, the movement is not performed (S365 in FIG. 5). At this time, whether or not the movement route is set within a range in which the vehicle 3 can move depends on how much the movement route input by the driver is deviated from the direction in which the vehicle 3 can move from the direction in which the vehicle 3 cannot move ( For example, when the vehicle 3 deviates by 60 degrees or more from the direction in which the vehicle 3 can move, the vehicle 3 may be out of the allowable range so that the vehicle 3 is not moved.

Next, the route analysis process (S150 in FIG. 2) will be described with reference to FIG. FIG. 8A is a flowchart showing route analysis processing executed by the terminal control device 43.
In the route analysis process shown in FIG. 8A, in S500, based on the vehicle length of the vehicle 3 in the vehicle information transmitted from the vehicle guidance ECU 32, how many times this vehicle length is set. To calculate the distance of the moving route.

  In S510, the travel route is divided into several sections, and the speed and the steering angle are determined for each of the divided sections based on the shape of the travel path and the distance of the travel path. The speed determined at this time is set to a maximum speed that is sufficiently slow and does not require rapid acceleration and braking, for safety reasons.

Next, in S520, the determined speed and steering angle information is stored in the RAM 43C for each divided section, and the route analysis process is terminated.
Next, the vehicle operation process (S160 in FIG. 2) will be described with reference to FIG. FIG. 8B is a flowchart showing a vehicle operation process executed by the terminal control device 43.

  In the vehicle operation process shown in FIG. 8B, it is determined in S600 whether or not the driver has depressed the transmission button. If it is determined that the driver has depressed the transmission button, the process proceeds to S610, and if it is determined that the driver has not depressed the transmission button, S600 is repeated.

In S610, the speed and steering angle information stored in S520 of the route analysis process (FIG. 8A) is transmitted to the vehicle guidance ECU 32, and the process proceeds to S620.
In S620, it is determined whether a signal indicating that the preparation of the vehicle 3 is completed is received from the vehicle guidance ECU 32. If it is determined that the signal indicating that the preparation of the vehicle 3 is completed is received from the vehicle guidance ECU 32, the process proceeds to S630, and if it is determined that the signal indicating that the preparation of the vehicle 3 is completed is not received from the vehicle guidance ECU 32. , S620 is repeated.

In S630, the display unit 42B displays that the preparation of the vehicle 3 is completed, and the process proceeds to S640.
In S640, it is determined whether the driver has depressed the operation button or the end button. If it is determined that the driver has depressed the end button, the process proceeds to S690. If it is determined that the driver has depressed the operation button, the process proceeds to S650, and if it is determined that no button is depressed, S640 is repeated.

Next, in S650, an operation signal for starting the vehicle motion process is transmitted to the vehicle guidance ECU 32, and the process proceeds to S660.
In S660, it is determined whether or not the driver has pressed the stop button. If it is determined that the driver has pressed the stop button, a signal for stopping the vehicle motion process is transmitted to the vehicle guidance ECU 32 in S670, and the process proceeds to S680. If it is determined in S660 that the driver has not depressed the stop button, the process proceeds to S680 as it is.

  Next, in S680, it is determined whether or not an end signal indicating that the vehicle motion process is ended is received from the vehicle guidance ECU 32. If it is determined that a signal to end the vehicle motion processing has been received, the process proceeds to S690, and if it is determined that a signal to end the vehicle motion processing has not been received, the process returns to S660.

In S690, the display unit 42B is displayed to end the vehicle motion process, and the vehicle operation process ends.
Next, the vehicle motion process executed by the vehicle guidance ECU 32 will be described with reference to FIG. 9 in association with the vehicle operation process detailed in FIG. FIG. 9A is a flowchart showing a vehicle motion process, and FIG. 9B is a flowchart showing a stop process for stopping the vehicle motion process.

  The vehicle motion process shown in FIG. 9A determines whether or not the information on the speed and the steering angle from the terminal control device 43 is received in S700 (corresponding to S610). If it is determined that the information on the speed and the steering angle is received, the process proceeds to S710, and if it is determined that the information on the speed and the steering angle is not received, S700 is repeated.

  In S710, the control amount of the accelerator 36 (throttle opening) and the brake 37 is calculated for each divided section based on the speed information transmitted from the terminal controller 43, and the steering angle transmitted from the terminal controller 43 is calculated. Is stored in the RAM 32C of the vehicle guidance ECU 32.

Next, in S720, a signal indicating that the preparation of the vehicle 3 is completed is transmitted to the terminal control device 43 (corresponding to S620).
Next, the process proceeds to S730. In S730, it is determined whether an operation signal is received from the terminal control device 43 (corresponding to S650). If it is determined that the operation signal has been received, the process proceeds to S740. If it is determined that the operation signal has not been received, S730 is repeated.

  In S740, the accelerator 36, the brake 37, and the steering wheel 35 are controlled based on the control amount of the accelerator 36 and the brake 37 calculated in S710 and the information of the steering angle, and the vehicle 3 is actually guided, and the vehicle When the guidance of 3 is completed, the process proceeds to S750.

In S750, an end signal to end the vehicle motion process is transmitted to the terminal control device 43 (corresponding to S680), and the vehicle motion process is ended.
In S740, during the guidance of the vehicle 3, a stop process as shown in FIG. 9B can be executed by an interrupt process.

  9B is activated when a stop signal is received from the terminal control device 43 (corresponding to S670), the guidance of the vehicle 3 is stopped in S800, and an end signal is sent in S810. It transmits to the terminal control apparatus 43. Thereafter, the cancellation process ends.

In this way, guidance of the vehicle 3 is executed by the vehicle guidance device 1.
Here, the processing shown in S710 in the route analysis processing in FIG. 8A and the vehicle motion processing in FIG. 9A corresponds to the control amount calculation means in the present invention. Of the vehicle operation processes shown in FIG. 8B, the processes shown in S660 and S670 and the stop process shown in FIG. 9B correspond to the vehicle stop means in the present invention.

  In the vehicle guidance device 1 described in detail above, when the driver who has visually recognized the image around the vehicle 3 displayed on the display unit 42B inputs the movement route to the target stop position using the touch panel display 42, the ROM 32B The terminal control device 43 determines whether or not the movement route is within the movable range of the vehicle 3 based on the vehicle information stored in the vehicle information, and that the movement route is within the movable range of the vehicle 3. When the determination is made (S320: YES), the movement route is stored in the RAM 43C, and the vehicle guidance ECU 32 is configured to guide the vehicle 3 to the target stop position according to the movement route stored in the RAM 43C.

Accordingly, since the movement route stored in the RAM 43C is always within the range in which the vehicle 3 can move, the vehicle 3 can be guided along the set movement route.
In addition, the terminal control device 43 is input even when it is determined that the movement route input by the driver using the touch panel display 42 is outside the movable range of the vehicle 3 (S320: NO). If the travel route is within the allowable range (S350: YES), the travel route is corrected within the range in which the vehicle 3 can move, and the modified travel route is stored in the RAM 43C. It is possible to prevent re-input, and in turn, it is possible to shorten the travel route input time by the driver.

  Further, since the wheel base length and the maximum steering angle are stored in the ROM 32B as specific vehicle information, a path through which the vehicle 3 can move more accurately is determined from the wheel base length and the maximum steering angle. Can be calculated.

  In addition, the vehicle guidance ECU 32 calculates the control amounts of the accelerator 36 (throttle opening), the brake 37, and the steering 35 (steering angle) based on the movement route stored in the RAM 43C by the control amount calculation means. Since the vehicle 3 is configured to automatically steer based on the result, when the vehicle 3 is actually moving, it is not necessary for the driver to perform an operation on the vehicle 3. It is possible to concentrate only on the safety confirmation around the vehicle 3.

  Further, the display unit 42B and the touch panel display 42 are arranged on the mobile terminal 4, and the vehicle 3 and the mobile terminal 4 are configured to be able to transmit and receive data wirelessly, so that the driver does not get into the vehicle 3 The vehicle 3 can be remotely operated.

  Further, the ROM 32B for storing vehicle information is configured to be mounted on the vehicle 3. The ROM 32B stores vehicle information corresponding to only the vehicle 3, and when guiding other vehicles, Since the ROM storing the vehicle information only needs to be mounted on the vehicle, a plurality of vehicles 3 are guided using the portable terminal 4 without storing a huge amount of vehicle information in the ROM 32B. Can do.

  In addition, in the vehicle guidance device 1, the automatic guidance of the vehicle 3 performed by the vehicle guidance ECU 32 using the portable terminal 4 can be stopped, so that obstacles such as pedestrians and other vehicles move during the guidance of the vehicle 3. The vehicle 3 can be stopped when it appears on the route. Therefore, an accident can be prevented.

  Further, the camera 21 images the vehicle 3 from above the vehicle 3, and the image captured by the camera 21 is transmitted wirelessly to the mobile terminal 4 and displayed on the display unit 42 </ b> B. By capturing the scenery around the vehicle 3 from the information, the distortion of the captured image displayed on the display unit 42B can be reduced. As a result, the visibility of the captured image when the driver inputs the travel route can be improved.

  Furthermore, since the display part 42B and the operation input part 42A are comprised by the touchscreen display 42, the driver | operator can make easy the input of a movement path | route on the screen which displayed the image.

  Moreover, since the portable terminal 4 can display the movement route memorize | stored in RAM43C on the display part 42B before the guidance of the vehicle 3 (S390), the movement of the vehicle 3 based on the movement route inputted accidentally is prevented. can do.

  Furthermore, since the vehicle guidance device 1 implements the route determination process shown in FIG. 5 by computer processing according to the route determination program stored in the ROM 43B, is the movement route input by the driver within the movable range of the vehicle 3? It is possible to store the movement route while instantaneously determining whether or not. Accordingly, it is possible to shorten the time for inputting the movement route.

  By the way, in the vehicle guidance device 1 described in detail in the present embodiment, the steering 35, the accelerator 36, and the brake 37 are controlled to automatically steer the vehicle 3, but it is not particularly necessary to configure in this way. For example, only the steering load may be controlled to assist the driver in maneuvering the vehicle 3.

  Further, in the vehicle guidance device 1 of the present embodiment, a region through which the front and rear wheels of the vehicle 3 can pass is calculated from the vehicle length, the wheel base length, the maximum steering angle, and the wheel position, and a captured image is based on this region. Although it is configured to set the movable range of the vehicle 3 from the whole, it is not particularly necessary to configure in this way, and the movable range of the vehicle 3 is set only from the minimum turning radius of the vehicle 3. Also good.

  Furthermore, in the vehicle guidance device 1 in the present embodiment, the vehicle information is stored in the ROM 32B of the vehicle guidance ECU 32. However, there is no particular need to do this, for example, in the terminal control device 43 of the portable terminal 4. Vehicle information may be stored. In this case, when it is going to guide a plurality of vehicles 3 using this portable terminal 4, vehicle information about many vehicles 3 (vehicle types) is stored in ROM 32B, and a movement route of vehicles 3 is input. It is conceivable that the vehicle information to be used is configured to be selected from a lot of vehicle information before the operation is performed.

  In addition, in the vehicle guidance device 1 according to the present embodiment, the camera 21 is configured to image the vehicle 3 from above the parking lot 2, but it is not particularly necessary to do so. For example, the camera 21 is connected to the vehicle 3. It may be configured to take a scene in the traveling direction of the vehicle 3 and display the image on the display unit 42B. In this case, since the captured image is a bird's-eye view image and not a plan view image, the bird's-eye view image described in, for example, JP-A-2002-362271 (Patent Document 1) is converted into a plan view image so as to be a plan view. It is only necessary to configure the driver to input a movement route after converting the image into a plan view image using an image processing technique.

  Moreover, in the vehicle guidance device 1 according to the present embodiment, when the driver inputs the movement route, the movement route is continuously input while touching the touch panel display 42 (operation input unit 42A). In particular, it is not necessary to configure in this way, and the operation input unit 42A and the button operation unit 44 may be configured by a keyboard or the like, for example. In this case, when the driver inputs the travel route, for example, the driver may input several passing points to pass the vehicle 3 using a keyboard.

  Furthermore, in the vehicle guidance device 1 in the present embodiment, the GPS receiver 33 is used to specify the position of the vehicle 3, but it is not particularly necessary to configure in this way. For example, the movement history of the vehicle 3 in the past The position of the vehicle 3 may be estimated from the above.

  In S236 of the screen display process (see FIG. 3), when it is determined that a fixed time has elapsed in S215 or S235, an error is displayed and the screen display process is terminated. For example, a signal for returning the imaging control device 23 of the parking lot 2 or the vehicle guidance ECU 32 of the vehicle 3 to a normal state may be transmitted, and the screen display process may be executed again. .

  Even in the above-described manner, the same effect can be obtained.

It is a block diagram showing a schematic structure of a vehicle guidance device to which the present invention is applied. It is a flowchart which shows a vehicle guidance process. It is a flowchart which shows a screen display process. It is explanatory drawing which shows the example of a display of the initial screen displayed on a portable terminal. It is a flowchart which shows a route determination process. It is explanatory drawing which shows the procedure at the time of a driver | operator inputting the movement path | route of a vehicle. It is explanatory drawing which shows the tolerance | permissible_range at the time of a driver | operator inputting the movement path | route of a vehicle. It is the flowchart (A) which shows a route analysis process, and the flowchart (B) which shows a vehicle operation process. It is a flowchart which shows a cancellation process.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Vehicle guidance device, 2 ... Parking lot, 3 ... Vehicle, 4 ... Portable terminal, 21 ... Camera, 22 ... Antenna, 23 ... Imaging control device, 31 ... Antenna, 32 ... Vehicle guidance ECU, 32A ... CPU, 32B ... ROM, 32C ... RAM, 33 ... GPS receiver, 34 ... gateway, 35 ... steering, 36 ... accelerator, 37 ... brake, 41 ... antenna, 42 ... touch panel display, 42A ... operation input unit, 42B ... display unit, 43 ... terminal control device, 43A ... CPU, 43B ... ROM, 43C ... RAM, 44 ... button operation unit, 45 ... speaker.

Claims (11)

An imaging means for capturing an image around the vehicle;
Display means for displaying an image picked up by the image pickup means together with the vehicle;
Route input means for inputting a route required for the driver to move the vehicle to the target stop position based on the image displayed on the display means;
Route storage means for storing the movement route input by the driver;
Guidance control means for guiding the vehicle to the target stop position according to the travel route stored by the route storage means;
In a vehicle guidance device comprising:
Vehicle information storage means for storing vehicle information representing the turning performance of the vehicle;
When a travel route is input via the route input means, it is determined based on the vehicle information whether the vehicle is movable along the travel route, and the vehicle travels along the travel route. A route determination means for permitting storage of a movement route by the route storage means when possible;
A vehicle guidance device comprising:   The vehicle guidance device according to claim 1, wherein the vehicle information storage means stores at least a wheelbase length and a maximum steering angle as the vehicle information. The guidance control means includes
Control amount calculation means for calculating control amounts of the drive device, the braking device, and the steering device based on the movement route stored by the route storage means;
The vehicle guidance device according to claim 1, further comprising: an automatic steering unit that automatically controls the vehicle based on a calculation result by the control amount calculation unit. The vehicle guidance device according to claim 3, wherein the display unit and the route input unit are configured separately from the vehicle.   The vehicle guidance device according to claim 4, wherein the vehicle information storage unit is mounted on the vehicle.   The vehicle according to any one of claims 3 to 5, further comprising vehicle stop means for stopping automatic steering of the vehicle performed by the automatic steering means in accordance with a command from the outside and stopping the vehicle. Guidance device. The imaging means images the vehicle from above the vehicle,
The vehicle guidance device according to any one of claims 1 to 6, wherein an image captured by the imaging unit is wirelessly transmitted to and displayed on the display unit.   The vehicle guidance device according to claim 1, wherein the display unit and the route input unit are configured by a touch panel display.   The route determination means corrects the input movement route within a range in which the vehicle can move when the vehicle cannot move along the movement route input via the route input means. The vehicle guidance device according to any one of claims 1 to 8, wherein storage of the movement route by the storage unit is permitted.   The vehicle guidance according to any one of claims 1 to 9, further comprising route display means for displaying the movement route on the display means when the movement route is stored in the route storage means. apparatus. The route determination program for implement | achieving the function as a route determination means in the vehicle guidance apparatus in any one of Claims 1-10 by computer processing.

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