JP2008114691A - Vehicular periphery monitoring device, and vehicular periphery monitoring image display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vehicular periphery monitoring device having the high parking position accuracy when a vehicle is parked, and performing the safe parking operation. <P>SOLUTION: The vehicular periphery monitoring device comprises an image pickup means for picking up an image of a part of a one's own vehicle 1 and a peripheral road surface of the one's own vehicle 1 by a plurality of cameras (for example, a first camera 4a, a second camera 4b and a third camera 4c), a top view image conversion means for converting an image picked up by the image pickup means into a top view image 6, and a display for displaying a top view image 6 converted by the top view image conversion means. In the top view image, a part of the picked-up image of the one's own vehicle 1 expresses an outline shape of the one's own vehicle. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention assists the driver's visual sense when the vehicle (vehicle) is parked in a parking lot or passes through a gorge, and assists the driver's vision. The present invention relates to a vehicle periphery monitoring device and a vehicle periphery monitoring video display method for assisting grasping.

In order to make it easier to understand the situation around the host vehicle when parked, all or part of the road surface around the host vehicle was photographed using multiple cameras, and the road surface around the host vehicle was viewed from the sky by image conversion. There is a system that converts this into an image and displays it on a display.
Such image conversion is called top view conversion.
FIG. 6 is an example of a display screen of a conventional vehicle periphery monitoring device (parking assist device) disclosed in Japanese Patent Laid-Open No. 2005-035542 (Patent Document 1).
A display screen 700 of a display (not shown) mounted inside the vehicle is displayed by converting the rear image 700A of the host vehicle and the image of the periphery of the vehicle captured by the camera (CCD camera) provided in the host vehicle from the top view. And a top view image 700B.
The rear image 700A is a direct rear view image captured by a wide-angle camera installed at the rear center of the host vehicle.

FIG. 6 shows an image displayed on the display screen 700 when the vehicle is parked while backing between the other vehicle 120 and the other vehicle 130 that are already parked. For example, in the rear image 700A of the host vehicle, Displays images of the other vehicle 120 parked behind the host vehicle, the predicted trajectory 230 of the host vehicle, a part 240 of the host vehicle photographed by a camera installed behind the host vehicle, the parking frame 300, and the like. ing.
In addition, in the top view image 700B displayed by converting the image around the vehicle to the top view, the other vehicle 120, the other vehicle 130, and the self-vehicle schematic image 210 representing the position and size of the own vehicle are already displayed. Images of a parking path 220 that is a path when the host vehicle is parked, an expected trajectory 230 when the host vehicle is moving, a parking frame 300, and the like are displayed.

As described above, the parking assist device disclosed in Patent Document 1 captures the peripheral view of the host vehicle with the camera, and displays the peripheral image of the host vehicle on the display device (display) based on the video from the camera. A second image viewed from a second viewpoint that is different from the first viewpoint while creating a first image viewed from the first viewpoint based on video captured by the camera (that is, the rear video 700A). (Ie, a top view image 700B) is created, and the first image and the second image are displayed on a display device (display) during parking operation, so that the driver can grasp the relative positional relationship between the obstacle and the host vehicle. It is.
Japanese Patent Laying-Open No. 2005-035542 (FIG. 1, summary)

As described above, in the conventional parking assistance device (that is, the vehicle periphery monitoring device), in order to display the rough image 210 of the host vehicle indicating the host vehicle position and the size of the host vehicle in the top view image 700B, Hidden in the sketch 210 of the host vehicle, the true end of the host vehicle and the road surface directly below the host vehicle end could not be seen.
Further, since it is inevitable that the position of the rough sketch 210 of the own vehicle is slightly deviated from the actual position of the own vehicle, it is difficult to perform a highly accurate parking operation.

In addition, the expected trajectory 230 drawn on the rear video 700A and the top video 700B, which are direct back images taken by a wide-angle camera installed in the center of the rear of the host vehicle, is actually the weight balance of the passengers If the error due to the condition of the suspension or the like is not accurately corrected, the error will be large.
Therefore, although the predicted trajectory 230 is only a guideline for parking in practice, there is a problem that it becomes conspicuous on the display screen and the road surface becomes difficult to see.

  In addition, in the conventional example, the predicted trajectory 230 drawn on the rear video 700A is originally drawn on a video with a large amount of distortion, so that it is difficult to intuitively understand the course of the host vehicle. .

  The present invention has been made in order to solve the problem as described above. It is possible to visually recognize the road surface near the end portion of the own vehicle and to intuitively understand the course of the own vehicle with a clean screen. An object of the present invention is to obtain a vehicle periphery monitoring device and a vehicle periphery monitoring video display method that are easy to understand.

  The vehicle periphery monitoring apparatus according to the present invention includes an imaging unit that captures a part of the host vehicle and a road surface around the host vehicle using a plurality of cameras, and a top view that converts an image captured by the imaging unit into a top view image. Video conversion means and a display for displaying the top view video image converted by the top view video conversion means, wherein the top view video image shows a rough shape of a part of the host vehicle. It is what.

  The vehicle periphery monitoring video display method according to the present invention includes an imaging step of imaging a part of the host vehicle and a surrounding road surface of the host vehicle with a plurality of cameras, and the video captured in the imaging step is converted into a top view video. A top view image conversion step for converting, and a display step for displaying the top view image converted in the top view image conversion step, wherein the top view image displayed in the display step is A part represents the general shape of the host vehicle.

  According to the vehicle periphery monitoring device or the vehicle periphery monitoring video display method according to the present invention, a part of the own vehicle reflected at the same time as the road surface represents the general shape of the vehicle. It is possible to see the road surface immediately below the end of the vehicle and the end of the host vehicle, and the parking position accuracy is high and a safe parking operation can be performed.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
In the drawings, the same reference numerals represent the same or equivalent ones.
Embodiment 1 FIG.
FIG. 1 is an overall view showing a scene when a parking operation is performed using the vehicle periphery monitoring device according to Embodiment 1 of the present invention.
In FIG. 1, the driver of the vehicle 1 is the own vehicle, 2a and 2b are parked other vehicles, 3 is a parking frame (that is, a line indicating a parking area), and 4a is installed above the rear part of the own vehicle. The first camera 4b is a second camera installed on the right door mirror of the host vehicle 1.
A third camera 4c (not shown) is also installed on the left door mirror.
Images taken by these cameras are processed into a “top view image” by a controller (not shown) of the vehicle periphery monitoring device, and then displayed on a display device (also simply referred to as a display) of the vehicle periphery monitoring device (not shown). Is done.
Reference numeral 5 denotes a display screen of a display device (display).

FIG. 2 shows an example of a display screen displayed on the display device of the vehicle periphery monitoring device installed in the host vehicle 1.
In FIG. 2, 5 is a display screen of the display, and 6 is a top view image.
Reference numeral 7 denotes an area that is not used for displaying the top view image 6 on the display screen 5 of the display, and is a display area for information other than the top view image (for example, a navigation screen).
The top view image 6 includes an image portion 6a obtained from the first camera 4a installed above the rear portion of the host vehicle 1, and an image portion 6b obtained from the second camera 4b provided in the right door mirror. It consists of a video portion 6c obtained from a third camera 4c (not shown) provided in the left door mirror.
Note that the top view image 6 includes images 9a, 9b, and 9c showing a part of the host vehicle captured by the first to third cameras.
The image 9a is an image of the rear of the host vehicle captured by the first camera 4a installed above the rear of the host vehicle, and the image 9b is captured by the second camera 4b installed on the right door mirror. The video image 9c showing the right side of the host vehicle is a video image showing the left side of the host vehicle captured by the third camera 4c installed on the right door mirror.

30a is an image of the other vehicle 2a taken by a third camera 4c (not shown) provided on the left door mirror, and 30b is an image of the other vehicle 2a taken by the first camera 4a provided at the rear. , 30c is an image of the other vehicle 2b imaged by the second camera 4b provided in the right door mirror, and 30d is an image of the other vehicle 2b imaged by the first camera 4a provided at the rear. The video is a video that has been converted from a top view.
The top view conversion is conversion that makes the road surface look as if it is viewed from the sky. Therefore, if the object with height is converted to the top view, the image is distorted.
For this reason, a large step is generated at the joint between the video 30a and the video 30b and at the joint between the video 30c and the video 30d. This is an unavoidable drawback of top view conversion.
In FIG. 2, since the video separation line 12 described later is formed at the joint of the video, the video seam itself is not displayed.

The top-view images 6a, 6b, and 6c are arranged so that the end portions of the own-vehicle images 9a, 9b, and 9c are substantially in the shape of a rectangular host vehicle that represents the length and width of the own-vehicle. Yes.
That is, a contour portion representing the approximate shape of the host vehicle is formed by the end portions of the top view images 6a, 6b, and 6c, so that the approximate shape of the host vehicle can be easily recognized.
Thus, the position and size of the host vehicle can be confirmed without drawing a rough image representing the host vehicle as in the prior art.
In the sketch of the own vehicle in the conventional example, it is unavoidable to include some accuracy error. Therefore, in order to absorb this, it is necessary to draw a slightly larger size.
For this reason, there is an inconvenience that the road surface in the vicinity immediately below the own vehicle end is hidden. However, according to the present embodiment, the road surface in the vicinity immediately below the own vehicle end can be visually recognized.

In addition, since the connection between the image 9a showing the rear part of the host vehicle and the images 9b and 9c showing the side surface of the host vehicle is an angled line passing through the corner of the rough shape of the host vehicle or the vicinity thereof, the road surface There is an effect that it is easy to grasp the general shape of the host vehicle even when the colors of the host vehicle are close.
In particular, this effect is significant when there is a difference in the color of the side, front or rear of the host vehicle.
Further, even when the side surface, front surface, or rear surface of the host vehicle are the same color, the brightness of each part usually varies depending on how the light strikes.
Therefore, there are many cases where it is easy to confirm an oblique line indicating the seam of the image, and it is easy to confirm the corner portion of the rough shape of the host vehicle which is the end of the seam (diagonal line) of the image.

Moreover, in FIG. 2, 8 is a schematic drawing showing the four wheels of the own vehicle arrange | positioned on a top view image.
That is, on the top view image 6, a schematic image 8 representing the wheel of the host vehicle 1 is superimposed and displayed.
The direction of the sketch 8 representing the wheel moves according to the steering angle of the steering wheel, and the direction of the wheel of the host vehicle can be confirmed on the top view image.
This makes it possible to intuitively estimate the movement of the host vehicle without drawing an expected trajectory of the host vehicle as in the past, and a clean screen can be obtained.

As described above, the vehicle periphery monitoring device according to the present embodiment is an imaging means (for example, the first camera 4a, the first camera 4a) that images a part of the host vehicle 1 and the road surface around the host vehicle 1 with a plurality of cameras. The second camera 4b, the third camera 4c), a top view video converting means for converting the video imaged by the imaging means into a top view video 6, and a top view video 6 converted by the top view video conversion means. In the top view video, a part of the captured image of the host vehicle 1 represents the approximate shape of the host vehicle.
As a result, the driver of the vehicle can visually recognize the end of the own vehicle and the road surface immediately below the end of the own vehicle by the top view image displayed on the display, and the parking position accuracy is high. Safe parking is possible.

Further, in the vehicle periphery monitoring device according to the present embodiment, the top view image 6 is an image captured by a camera (for example, the second camera 4b or the third camera 4c) provided on the side surface of the host vehicle 1. And the joints of the images taken by the cameras (for example, the first camera 4a and the fourth camera 4d) provided before and after the host vehicle 1, the corners of the approximate shape of the host vehicle or the vicinity of the corners The diagonal line that passes through.
Therefore, it is easy to grasp the general shape of the host vehicle even when the road surface and the host vehicle are close in color.
This effect is particularly noticeable when there is a difference in color between the side and front or back, but even in the case of the same color, the brightness of each part usually varies depending on how the light strikes. It is easy to check the seam of the vehicle, and it is easy to check the corner of the vehicle's general shape, which is the end of the joint.

Further, in the vehicle periphery monitoring device according to the present embodiment, the schematic image 8 representing the wheels of the host vehicle 1 is superimposed on the top view image 6 so that the position of the wheels and the direction of the wheels of the host vehicle 1 are indicated. Easy to grasp as an image.
In addition, the vehicle periphery monitoring device according to the present embodiment includes a steering angle sensor, and changes the direction of the rough image representing the wheel according to the steering angle, so that it is cleaner than when drawing an expected locus as in the past. It is easy to grasp the movement of the vehicle on the screen.

Embodiment 2. FIG.
FIG. 3 is a diagram showing a display screen displayed on the display by the vehicle periphery monitoring device according to the second embodiment in a situation where the same parking operation as that in FIG. 1 is performed.
In FIG. 3, 10 a is a right rear direct view image taken by a second camera 4 b (not shown) provided on the right door mirror displayed on the right side of the top view image 6, and 10 b is a left side of the top view image 6. The left rear direct view image | video image | photographed by the 3rd camera 4c (not shown) with which the left door mirror displayed on FIG.
Since the top view image 6 is mainly for projecting the road surface in the vicinity of the host vehicle, a distant image is not captured, and an object with a height looks unnatural.

However, by disposing the right rear direct view image 10a and the left rear direct view image 10b on the display screen of the display, it is possible to confirm the situation of the rear farther with a natural image.
In addition, the direct view image here refers to an image having a horizontal angle of view of approximately 60 degrees or less (approximately 35 mm or more in terms of the focal length of a 35 mm film camera), and a noticeable image distortion in a wide angle image. Point to.

In the first embodiment, the case where the top view images 6a, 6b, and 6c are mainly connected without gaps has been described. However, in the second embodiment, as shown in FIG. 3, the top view images 6a, 6b are displayed. , 6c and the joints between the rear direct view images 10a and 10b are clearly shown by the image separation line 12.
Depending on your preference, it is easier to understand the meaning of each image by clearly indicating the joints between the top view images 6a, 6b, 6c and the rear direct view images 10a, 10b with the image separation line 12. It may be easy.

As described above, in the vehicle periphery monitoring device according to the present embodiment, the display screen 5 displayed on the display is the front right side or the right side of the host vehicle 1 captured by the camera provided on the right side surface of the host vehicle 1. A rear right-side direct view image (for example, right rear direct-view image 10a) is arranged and displayed on the right side of the top view image 6 and is displayed on the left side of the host vehicle 1 captured by a camera provided on the left side surface of the host vehicle 1. Alternatively, the left direct view image (for example, the left rear direct view image 10b) at the left rear is arranged and displayed on the left side of the top view image 6.
For this reason, it is possible to confirm the situation in the front or rear far away from the angle of view of the top view image on the display screen of the display by the direct view image with less distortion.

Further, in the vehicle periphery monitoring device according to the present embodiment, the video imaged by each camera and displayed on the display screen 5 of the display is separated by the video separation line 12.
As described above, in this embodiment, each video is separated by the video separation line for each source, so that the meaning of the displayed video can be easily understood.

Embodiment 3 FIG.
FIG. 4 is a panoramic view showing a scene in which a vehicle passing operation on a gorge is performed using the vehicle periphery monitoring device according to the third embodiment.
In FIG. 4, 1 is the host vehicle, 2 c is an oncoming vehicle, 4 b is a second camera installed on the right door mirror of the host vehicle 1, and 4 c is a third camera installed on the left door mirror of the host vehicle 1.
A fourth camera 4d (not shown) is also installed at the center of the front end of the host vehicle 1.
Images taken by these cameras (that is, the second to fourth cameras) are processed into a top view image by a controller (not shown) of the vehicle periphery monitoring device and then displayed on the display screen 5 of the display.

FIG. 5 is a diagram showing a display screen 5 displayed by the display of the vehicle periphery monitoring device according to the third embodiment.
In the display screen 5 of the display shown in FIG. 5, 6 is a top view image, and the top view image 6 includes a portion 6b obtained from the image of the second camera 4b provided in the right door mirror, and the left door mirror. And a portion 6c obtained from the image of the third camera 4c provided in the vehicle, and a portion 6d obtained from a fourth camera (not shown) installed above the front portion of the host vehicle 1.
Further, in FIG. 5, an image 10 c displayed on the right side of the top view image 6 is displayed on the left side of the right front direct view image and the top view image 6 taken by the second camera 4 b provided on the right door mirror. The image 10d is a left front direct view image taken by the second camera 4c provided in the left door mirror.

In the right front direct view image 10c and the left direct view image 10d, a lateral position guide line 15 is drawn on a line extending in the front-rear direction of the host vehicle from the road surface just below the camera installation position.
On the lateral position guide line 15, a vehicle end guide mark 16 is drawn at a position where the tip of the host vehicle 1 is projected on the road surface.
The horizontal position guide line 15 extends straight above the display screen 5.
Therefore, as long as the host vehicle 1 goes straight, the obstacle on the right side of the lateral position guide line 15 is outside the body of the host vehicle, leaving at least a margin corresponding to the length of the door mirror, and does not touch the body. Clearly understood.
For this reason, it is possible to intuitively and accurately grasp the lateral position of the side surface of the host vehicle and the positional relationship between the obstacles, compared to the case of drawing an expected trajectory whose shape changes according to the steering angle as in the conventional case.
Further, since the vehicle end guide mark 16 is displayed, the position of the front end or the rear end of the host vehicle is known, and when the oncoming vehicle approaches very close, it is easy to grasp the sense of distance from the oncoming vehicle.

As described above, in the vehicle periphery monitoring device according to the present embodiment, the right direct view image (for example, the right front direct view image 10c) and the left direct view image (for example, the left front direct view image 10d) are A linear lateral position guide line 15 extending in the front-rear direction of the host vehicle from the road surface below the camera installation position provided on the right side surface or the left side surface of the vehicle 1 is displayed.
Therefore, when the host vehicle is traveling straight, it is clear that the obstacle on the right side of the lateral position guide line does not touch. For this reason, it is easy to intuitively and accurately grasp the lateral position of the side surface of the host vehicle.

In the vehicle periphery monitoring device according to the present embodiment, the right-hand direct view image 10c and the left-hand direct view image 10d display the vehicle end guide mark 16 at the position where the front end or rear end of the host vehicle 1 is projected on the road surface. is doing.
Therefore, the position of the front end or the rear end of the host vehicle can be grasped intuitively and accurately.

Other Embodiments In the second embodiment or the third embodiment described above, the directly viewed images are arranged on the left and right of the top view image 6, but only the directly viewed images may be displayed.
In the first to third embodiments, the cameras provided on the left and right door mirrors and the cameras provided on the front and rear portions are used. However, cameras provided in other locations of the vehicle may be used. The same effect is demonstrated.
In the first to third embodiments, all videos are displayed on one display, but may be displayed separately on a plurality of displays.

In addition, when the shift position is forward, the display position of the host vehicle is displayed below the top view image and the front direct view image is displayed when the shift position is forward. When the shift position is reverse, the display position of the host vehicle may be arranged to be above the top view image as in the second embodiment, and the rear direct view image may be displayed.
That is, the top view image is displayed with the display position of the host vehicle positioned below the top view image when the shift position is forward, and the display position of the host vehicle is positioned above the top view image when the shift position is reverse. May be.
Thus, in the top view image, when the shift position is forward, the display position of the host vehicle is moved downward to widen the front field of view, and when the shift position is reverse, the display position of the host vehicle is moved upward. It can move and widen the rear field of view, and can display a large field of view necessary for driving.

In addition, when the vehicle is steered to the right, the display position of the host vehicle is arranged to the left of the top view image, and when the vehicle is steered to the left, the display position of the host vehicle is arranged to the right of the top view image. good.
As a result, even if the vehicle is steered rightward or leftward, the field of view in the steering direction of the host vehicle can be widened, and the field of view necessary for driving can be displayed large in the top view image.
Further, the top view image and the direct view image do not necessarily have an actual aspect ratio, and when a wide area is to be displayed on a display having a narrow width, the image may be displayed by being compressed in the horizontal direction.
When the shift position is forward, the right-hand direct view image and the left-hand direct view image display a direct view image in front of the host vehicle. When the shift position is reverse, the right-hand direct view image and the left-hand direct view image are displayed. May display a direct view image behind the host vehicle.
Thereby, a required image can be obtained according to the driving situation.

  The present invention is useful for realizing a vehicle periphery monitoring device that has high parking position accuracy and can perform a safe parking operation when parking.

It is a figure which shows the scene at the time of parking operation using the vehicle periphery monitoring apparatus by this invention. It is a figure which shows the example of the display screen displayed on the display apparatus of the vehicle periphery monitoring apparatus by Embodiment 1. FIG. It is a figure which shows the example of the display screen displayed on the display apparatus of the vehicle periphery monitoring apparatus by Embodiment 2. FIG. It is a figure which shows the scene which is performing the passing operation | movement of the vehicle in a canyon using the vehicle periphery monitoring apparatus by Embodiment 3. FIG. FIG. 10 is a diagram illustrating an example of a display screen displayed on a display device of a vehicle periphery monitoring device according to a third embodiment. It is a figure which shows an example of the display screen in the conventional vehicle periphery monitoring apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Own vehicle 2a, 2b Other vehicle 3 Parking frame 4a-4d Camera 5 Display drawing 6, 6a, 6c Top view image 8 Wheel schematic image 9a-9c Own vehicle image 10a-10d Direct view image 12 Image separation line 15 Side position standard Line 16 Vehicle end guide mark 30a-10d Other car image

Claims (12)

Imaging means for imaging a part of the host vehicle and a road surface around the host vehicle with a plurality of cameras, top view video converting means for converting the video imaged by the imaging means into a top view video, and the top view video conversion A display for displaying a top view image converted by the means;
The vehicle periphery monitoring device, wherein the top view video has a part of the captured image of the host vehicle representing a schematic shape of the host vehicle.   The top view image is a joint between the image captured by the camera provided on the side surface of the host vehicle and the images captured by the cameras provided before and after the host vehicle. The vehicle periphery monitoring device according to claim 1, wherein the vehicle periphery monitoring device is an oblique line passing through the vicinity of a corner portion.   The vehicle periphery monitoring device according to claim 1, wherein a schematic image representing a wheel of the host vehicle is superimposed on the top view image.   The vehicle periphery monitoring device according to claim 3, further comprising a steering angle sensor, and changing a direction of a schematic image representing a wheel according to the steering angle.   The display screen displayed by the display displays a right-hand direct view image of the right front or right rear of the own vehicle imaged by a camera provided on the right side of the own vehicle on the right side of the top view image. 2. The left direct view image of the left front or left rear of the own vehicle imaged by a camera provided on the left side surface of the own vehicle is arranged and displayed on the left side of the top view image. The vehicle periphery monitoring device according to claim 1.   The vehicle periphery monitoring device according to claim 1 or 5, wherein images captured by each camera and displayed on a display screen of the display are separated by a video separation line.   The right-hand direct view image and the left-hand direct view image display a straight lateral position guide line extending in the front-rear direction of the host vehicle from the road surface below the installation position of the camera provided on the right side or left side of the host vehicle. The vehicle periphery monitoring device according to claim 5, wherein the vehicle periphery monitoring device is provided.   6. The vehicle periphery according to claim 5, wherein the right-hand direct view image and the left-hand direct view image display a vehicle end guide mark at a position where the front or rear end of the host vehicle is projected on the road surface. Monitoring device.   In the top view image, the display position of the host vehicle is disposed below the top view image when the shift position is forward, and the display position of the host vehicle is disposed above the top view image when the shift position is reverse. The vehicle periphery monitoring apparatus according to claim 1.   2. The display according to claim 1, wherein the top-view video is arranged such that a display position of the own vehicle is arranged to the left when the vehicle is steered rightward, and a display position of the own vehicle is arranged to the right when steered leftward. Vehicle periphery monitoring device.   When the shift position is forward, the right-hand direct view image and the left-hand direct view image are displayed in front of the host vehicle. When the shift position is reverse, the right-hand direct view image and the left-hand direct view image are displayed. 6. The vehicle periphery monitoring device according to claim 5, wherein a direct view image of the rear of the vehicle is displayed in the image. An imaging step for imaging a part of the host vehicle and a road surface around the host vehicle with a plurality of cameras, a top view video converting step for converting the video shot in the imaging step into a top view video, and the top view video conversion A display step for displaying the top view image converted in the step;
The vehicle periphery monitoring video display method, wherein the top-view video displayed in the display step shows that a part of the captured host vehicle represents an approximate shape of the host vehicle.

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