DE102005063445B4 - Rangierhilfe for drivers of vehicles or vehicle combinations, which consist of mutually bendable vehicle elements - Google Patents

Abstract

Method for driver assistance when maneuvering a vehicle or vehicle combination, in which this vehicle (1) consists of a plurality of mutually bendable vehicle elements (2, 3),
wherein at least one camera (9) captures image data from the rear environment of the vehicle (1),
wherein these image data, together with the data about the steering angle (7) at least one steerable axle (6) of the vehicle (1), as well as over the bending angle (5) at least between two vehicle elements (2, 3) are fed to a processor module,
which is based on the data on steering and articulation angle (5, 7) with knowledge of at least the geometry of the vehicle (1), the future course of driving in the circumference of the lane (21, 31, 32) and / or its towing lane (22, 33, 34 ) predicts
characterized,
that in addition to the image of the traffic lane (21, 31, 32) and / or the towing lane (22, 33, 34), additionally an image of the predicted course of movement of one or more corners of the vehicle symbolically symbolizes the image data recorded by the camera ...

Description

The Invention relates to a maneuvering aid for vehicles and vehicle combinations, which have mutually movable sections.

At the To lead In order to avoid accidents, it is necessary for the driver of the vehicle to do so Environment of the vehicle as optimal as possible can see. The detection of the vehicle environment takes place essentially by visual inspection by the driver. In particular, when maneuvering a vehicle arises due the driver's seating position, however, the problem that a large part of the vehicle rear space to be viewed through the vehicle body itself is hidden. To the solution This problem is a variety of mirror and lens designs for Attachment to the vehicle known. Also, it is recently proposed the back room to capture the vehicle using a camera device and The image data thus obtained the driver well visible on a Display in dashboard area.

In order to further assist the driver in addition to the camera image display in the reverse drive is in the writings EP 1 022 903 A2 and EP 1 102 226 B1 a maneuvering aid for motor vehicles proposed in particular for entry into parking spaces. For this purpose, a camera image of the rear space is presented to the driver on a display, on which overlaid, starting from the detected steering angle of the vehicle, the predicted route is displayed.

DE 10317044 A1 describes a clearance monitoring for motor vehicles, by means of a camera system, the environment of the motor vehicle is detected and thus the future driving course is displayed to the driver on a display unit. Furthermore, it is known from this document that the future driving course a symbolically represented virtual driving tube is superimposed. The representation of the virtual driving tube and the future driving course takes place as a function of the geometry of the motor vehicle, wherein records of different vehicle dimensions are stored.

From the DE 19526702 A1 For example, there is known a method of downshifting a road vehicle with a trailer. The trailer has a CCD camera, which detects the rear environment of the road vehicle. In order to determine the future course of the journey, track setpoints and a trajectory are calculated, whereby in addition to the image data, information about the geometry of the road vehicle as well as its steering angle and articulation angle are included.

task The invention is to provide an improved maneuvering aid, which for a wide range of motor vehicles is usable.

The The object is achieved by a device and a method with the features of the claims 1 and 9 solved. Advantageous embodiments and further developments of the invention will be by the subclaims described.

The driver assistance system for maneuvering is designed so that it can also be used to drive a vehicle or vehicle combination ( 1 ), in which this vehicle consists of several mutually bendable vehicle elements ( 2 . 3 ) consists. For this purpose, by means of a camera, the rear environment of the vehicle ( 1 ) detected. For detecting the steering angle ( 7 ) at least one steerable axle ( 6 ) of the vehicle ( 1 ), and for determining the bending angle ( 5 ) between at least two mutually bendable vehicle elements ( 2 . 3 ) Sensors are provided. These sensors may very well be mechanical or electro-mechanical sensors, but it is also conceivable that the sensor for detecting the bending angle (FIG. 5 ) between at least two vehicle elements or the steering angle ( 7 ), on an environment detecting sensor, in particular a camera or a radar / lidar, based, and the current kink angle ( 5 ) or steering angle ( 7 ) is estimated from the environmental data acquired thereby; So it would very well conceivable one of two mutually bendable vehicle elements ( 2 . 3 ) to be provided with a camera and determine the bend angle from the thus captured image data of the other vehicle element (this could be done analogously when using a radar or lidar system).

The image data acquired with the camera as well as the determined steering and tilt angles are fed to a processor module. This processor module consists at least of a unit for image data processing, as well as at least one memory, which stores the dimensions of the geometry, in particular the peripheral geometry ( 1 ) of the vehicle ( 1 ) includes.

Based on the data on steering and articulation angle ( 5 . 7 ) knowing at least the geometry of the vehicle ( 1 ), the future driving course of the vehicle ( 1 ) within the scope of its lane ( 21 . 31 . 32 ) and / or its towing lane ( 22 . 33 . 34 ) predicts and perspectively correct, symbolically superimposed on the image data recorded by the camera. Following this, the image data thus processed are displayed on an indication to the driver of the vehicle ( 1 ) for the maneuvering aid.

In a particularly advantageous manner, the Memory, which determines the geometrical dimensions of the vehicle ( 1 ) is designed so that it can be stored at the same time several different vehicle geometries. In this way it is particularly easy to adapt the driver assistance system when maneuvering to changes in the vehicle geometries (eg new trailers, other bodies, etc.). Such changes can be made without great technical effort in the system, for example, by entering the corresponding data of the new dimensions in the memory of the (mobile and / or stationary) data processing system. With an appropriate design, this can also be done wirelessly in particular. In the case of frequently repeated (same) changes (eg driving with a loaded or unloaded container), several different vehicle contours or dimensions may also be contained in the memory of the data processing system and may also be retrieved manually.

Around the driver one possible comprehensive insight into the rear environment present to be able to offers the use of an omnidirectional (catadioptric) Camera on. As a result, the number of cameras required for monitoring the back room can be be minimized

To display the data of the lane ( 21 . 31 . 32 ) and / or towing lane ( 22 . 33 . 34 Superimposed image data are particularly useful in the area of the dashboard displays or head-up displays, in which the image data to be displayed are projected onto existing surfaces in the vehicle, in particular the windshield. Nevertheless, the integration of the image display in or in the area of a rear-view mirror of the vehicle is also possible ( 1 ) at. This offers the advantage that the image display takes place in places which are regularly checked by the vehicle driver when the vehicle is being driven ( 1 ) must be viewed anyway; A combination of rear view mirror and camera image display thus leads to an ergonomic improvement of the shunting assistance.

Of course, it is advantageous for the driver assistance system during maneuvering when all steering and / or articulation angles ( 5 . 7 ) of the vehicle ( 1 ) and processed in the processor module. Similarly, it is very well conceivable to detect and take into account only the particularly strongly varying steering and / or bending angles. Even in such a limited embodiment of the invention can still be made a passable, acceptable for short distances prediction of the driving course in general.

following becomes the system according to the invention described in detail with the help of figures. It shows

1 the schematic structure of the system using the example of a articulated bus,

2 an exemplary representation of the driving course,

3 a variant of in 2 illustrated driving course.

1 schematically shows an articulated bus ( 1 ) consisting of two mutually bendable vehicle elements ( 2 . 3 ); not shown is the flexible outer wall connection ('accordion') of the vehicle elements. In the larger vehicle element ( 2 ) there is also the driver's seat ( 4 ) with an image display ( 10 ). The two vehicle elements ( 2 . 3 ) are by a joint ( 8th ) coupled together. Does a driver drive while driving the articulated bus ( 1 ) a steering movement through this leads to a joint ( 8th ) measurable change in the bending angle ( 5 ). The steering angle resulting from the steering movement ( 7 ) on the steerable axle ( 6 ) of the articulated bus ( 1 ) can be detected by suitable means and together with the bending angle ( 5 ) and the image data of the camera ( 9 ) to the processor unit of the driver assistance system.

2 shows by way of example a camera image processed in the processor module ( 11 ) on the picture display ( 10 ) The camera image ( 11 ) includes in particular a part ( 20 ) of the vehicle, as well as the contours ( 21 ) the towing lane and the lanes ( 22 ) of two wheels. Additionally, in the camera image ( 11 ) two objects ( 23 ), for example plants. In a particularly advantageous embodiment of the invention, the processor module also includes means for the classification of objects imaged in the image data, these being particularly profitably determined by the classification unit in their position and geometry and should be checked in terms of their Überfahrbarkeit; For example, manhole covers or low curbs can be driven over, while plants or significantly elevated structures (walls) can not be run over. In a particularly advantageous embodiment of the invention, in the context of the representation of the towing lane ( 21 ) or a lane ( 22 ) one or more distance lines ( 24 ) which assist the driver in estimating distances from the image representation. The distance between the distance lines ( 24 ) with respect to the real environment is preferably chosen with the same distance. It is conceivable as in 2 shown the distance lines ( 24 ) over the entire predicted track pattern shown, or to restrict the display to a certain distance. For this purpose, it would be conceivable that Be restriction and the number of shown distance lines ( 24 ) speed-dependent, in particular the shape that at lower speeds the display is limited to a smaller distance. Profitably, it would also be conceivable, regardless of the means of the distance lines ( 24 ) Improved visualization distance keeps the number of displayed distance lines constant.

3 shows a variant of the in 2 represented representation of the edited in the processor module image data. The according to 3 on the picture display ( 10 ) ( 36 ) also contain a part ( 20 ) of the vehicle, as well as the contours ( 21 ) the towing lane and the lanes ( 22 ) of two wheels. In contrast to 2 however, here the outlines ( 21 ) and the lanes ( 22 ) not to the edge of the display of the image display ( 10 ), but were limited to a certain distance range. In particular, a restriction to a subarea is available within which a prediction of the tracks to be displayed can still be made meaningfully, or within which the prediction still lies within a certain scattering bandwidth; It is particularly noteworthy that the observed bending angle between vehicle elements ( 2 . 3 ) in articulated vehicles ( 1 ) are already subject to strong variations within a short shunting distance.

In addition, in the in the 3 example shown the display of lane ( 21 . 31 . 32 ) and / or towing lane ( 22 . 33 . 34 ) graded in different design variants ( 31 . 32 ) respectively. ( 33 . 34 ). In addition to such a different line design, it is of course also possible to use different color designs. In this way, in particular different distance ranges can be emphasized in a simple and accessible manner; It would also be conceivable to emphasize levels of different dispersion bandwidths of the prediction.

Still in the image data ( 11 ) objectively represented objects in the back space of the vehicle ( 1 ) were in the image data ( 36 ) are overlaid by symbols (shaded circles). In this way, the driver is warned of objects without being distracted by unnecessary detail information. If one of the objects had been classified as passable, it would also be conceivable to "remove" this object from the image data by suitable image processing in order to free the representation of 'irrelevant' objects.

In the in the 2 and 3 illustrated examples, the lanes ( 21 . 31 . 32 ) of only two wheels. Similarly, it is also conceivable the lanes of all the wheels of the vehicle ( 1 ). In another embodiment of the invention, only those lanes (particularly 21 . 31 . 32 ) of the wheels are displayed, which are spaced furthest perpendicular to the currently predicted driving course. Such a representation would ensure a safe driving course even if the lane of one of the wheels would run out of the area of the towing lane in the course of maneuvering. It would also be possible in an advantageous embodiment of the invention conceivable supplementary or alternatively represent the predicted course of movement of one or more corners of the vehicle.

The Invention is as it were when used with tractors or other towing vehicles with one or more trailers or but with semi-trailers or articulated buses.

Claims (15)

Method for driver assistance in maneuvering a vehicle or vehicle combination, in which this vehicle ( 1 ) of several mutually bendable vehicle elements ( 2 . 3 ), wherein with at least one camera ( 9 ) Image data from the rear environment of the vehicle ( 1 ), this image data together with the data on the steering angle ( 7 ) at least one steerable axle ( 6 ) of the vehicle ( 1 ), as well as over the bending angle ( 5 ) at least between two vehicle elements ( 2 . 3 ) are fed to a processor module, which is based on the data on steering angle and angle ( 5 . 7 ) knowing at least the geometry of the vehicle ( 1 ), whose future driving course is within the scope of its lane ( 21 . 31 . 32 ) and / or its towing lane ( 22 . 33 . 34 ), characterized in that next to the image of the lane ( 21 . 31 . 32 ) and / or the towing lane ( 22 . 33 . 34 In addition, an image of the predicted movement pattern of one or more corners of the vehicle is symbolically superimposed on the image data recorded by the camera and the image data processed in this way is displayed on a display (FIG. 10 ) the driver of the vehicle ( 1 ) are displayed. A method according to claim 1, characterized in that all steering and / or articulation angle ( 5 . 7 ) of the vehicle ( 1 ). Method according to one of the preceding claims, characterized in that in the context of the superimposition of the image data recorded by the camera, the lanes ( 21 . 31 . 32 ) of all wheels of the vehicle. Method according to one of the preceding claims, characterized in that in the context of the superposition of the camera ( 9 ) recorded image data only the lanes ( 21 . 31 . 32 ) of those wheels which are the most widely spaced perpendicular to the currently predicted driving course. Method according to one of the preceding claims, characterized in that the display of lane ( 21 . 31 . 32 ) and / or towing lane ( 22 . 33 . 34 ) stepped in different design variants. Method according to one of the preceding claims, characterized in that in the image data parts of the vehicle ( 1 ). Method according to one of the preceding claims, characterized in that in the from the camera ( 9 ) detected image data objects are recognized and then highlighted in their display. Method according to claim 7, characterized in that that highlighting by symbolic overlay of an object representing Image data takes place. Device for driver assistance when maneuvering a vehicle or vehicle combination, in which this vehicle ( 1 ) out of several mutually bendable vehicle elements ( 2 . 3 ), comprising a camera ( 9 ) for capturing image data from the rear environment of the vehicle ( 1 ), comprising at least one sensor for detecting the steering angle ( 7 ) at least one steerable axle ( 6 ) of the vehicle ( 1 ), comprising at least one sensor for detecting the bending angle ( 5 ) between at least two vehicle elements ( 2 . 3 ), comprising a processor module connected to the camera ( 9 ), as well as the sensors for detecting steering and articulation angles ( 5 . 7 ), said processor module comprising at least one unit for image data processing and at least one memory containing dimensions of the geometry of the vehicle ( 1 ), and comprising a display unit ( 10 ) for displaying the image data edited in the processor module. characterized in that the device further comprises a means for predicting the future driving course, and which is thus connected to the display unit (10). 10 ) that the display next to the representation of the lane ( 21 . 31 . 32 ) and / or the towing lane ( 22 . 33 . 34 ), in addition the representation of the predicted course of movement of one or more corners of the vehicle ( 1 ). Apparatus according to claim 9, characterized in that it is in the camera ( 9 ) is an omnidirectional camera. Device according to one of claims 9 or 10, characterized in that the sensor for detecting the bending angle ( 5 ) between at least two vehicle elements or the steering angle ( 7 ), based on an environmental sensor, and the current kink angle ( 5 ) and / or steering angle ( 7 ) is estimated from the environmental data acquired thereby. Device according to one of claims 9 to 11, characterized in that the processor module associated memory is designed so that therein the geometries of several different possible geometries and / or constellations of the vehicle ( 1 ) are stored. Device according to one of claims 9 to 12, characterized that the processor module is a unit for detecting in the image data includes imaged objects. Device according to one of claims 9 to 13, characterized in that the display ( 10 ) is designed as a head-up display. Device according to one of claims 9 to 14, characterized in that the display ( 10 ) in or around one of the rearview mirrors of the vehicle ( 1 ) is installed.