WO2012175264A1 - Apparatus and method for positioning an external device with respect to a motor vehicle - Google Patents

Abstract

An apparatus according to the invention for positioning an external device (50), in particular a calibration device of a cruise control system or a lane-keeping assistant, with respect to a motor vehicle has a left-hand measuring unit (18) for positioning on a left-hand side of the motor vehicle, wherein the left-hand measuring device can be positioned in such a manner that a measuring target on a left-hand wheel of the motor vehicle and a left-hand target unit (14) of the external device (50) can be detected from the left-hand measuring unit. The apparatus also comprises a right-hand measuring unit (20) for positioning on a right-hand side of the vehicle such that a measuring target on a right-hand wheel (6) of the motor vehicle and a right-hand target unit (16) of the external device (50) can be detected from the right-hand measuring unit (20). Each of the two measuring units comprises a reference target (12, 44) which can be seen by the other measuring unit (18, 20) in each case, an image capture unit (38, 40) and an optical device (22, 30). The image capture unit (38, 40) has an image capture surface (72, 80, 88) with a first image area (74, 82, 90) for acquiring an image of the measuring target (8, 10) on the motor vehicle wheel (4, 6), with a second image area (76, 84, 92) for acquiring an image of the target units (14, 16) of the external device (50) and with a third image area (78, 86, 94) for acquiring an image of the reference target (12, 44). The optical device (22, 30) is arranged and designed so as to obtain an image of the measuring target (8, 10) of the motor vehicle wheel in the first image area (74, 82, 90), an image of the target units (14, 16) of the external device (50) in the second image area (76, 84, 92) and an image of the reference target (12, 44) in the third image area (78, 86, 94). The apparatus also comprises an evaluation device (42) which is designed to determine the position of the external device (50) with respect to the motor vehicle from the images of the measuring targets (8, 10) of the motor vehicle wheels, of the target units (14, 16) of the external device (50) and of the reference targets (12, 44), as acquired by the image areas of the two measuring units, by comparison with reference images of the measuring targets (8, 10) and of the target units (14, 16).

Description

 description

DEVICE AND METHOD FOR POSITIONING AN EXTERNAL DEVICE RELATING TO ONE

MOTOR VEHICLE

The invention relates to a device and a method for positioning an external device, in particular a calibration device of a cruise control system or a lane departure warning, with respect to a motor vehicle.

State of the art

Modern motor vehicles have a variety of systems, such as adaptive cruise control systems or lane departure warning systems, that assist the driver. These systems use optical detectors to detect the preceding vehicle or lane boundary lines. For a correct warning behavior, the viewing direction of the detection devices with respect to the motor vehicle must be known exactly. For this purpose, the detection devices on the motor vehicle are usually calibrated with the aid of an external calibration device which is mounted, for example, on a frame in a known position relative to the motor vehicle. Such

Calibration devices are relatively inflexible and require a lot of space.

Calibration devices whose position is determined to run away from the motor vehicle, require a variety of components and are therefore complicated and expensive.

It is therefore the object of the present invention to provide a flexible device and a flexible method for positioning an external device with respect to a motor vehicle, which are inexpensive and allow easy and reliable positioning with a small number of components.

This object is achieved by a device having the features of the independent device claim and by a method having the features of the independent method claim. Advantageous developments emerge from the dependent claims.

Disclosure of the invention A device according to the invention for positioning an external device relative to a motor vehicle comprises a device according to independent claim 1.

According to the invention, the number of components of the positioning device is reduced. There are only two units of measurement required, which can also be portable, which greatly simplifies their positioning relative to the vehicle. The positioning device according to the invention makes it possible to flexibly position the external device to the motor vehicle. The attachment of the external device at predetermined reference positions with known orientation to the motor vehicle is not necessary, whereby the number of components and the space requirement is significantly reduced. The positioning device according to the invention enables a reliable and error-free positioning of an external device with respect to a motor vehicle.

The positioning device comprises only two measuring units that determine its position relative to the motor vehicle by means of two wheels mounted on the target and two target unit on the external device.

A measuring unit of the device according to the invention comprises a reference target, an image acquisition unit and an optical device. The measuring unit can be positioned, for example, in a longitudinal position between the measuring target and the target unit of the external device of a respective motor vehicle side. For example, the left-hand measuring unit on the left-hand side of the motor vehicle may be positionable at a longitudinal position between a measuring target on a left-hand wheel of the motor vehicle and the left-hand target unit. In addition, it is possible to position the measuring units, for example, in the vehicle transverse direction, with the reference targets of the respective measuring units thus being opposite in the vehicle transverse direction.

The optical device is capable of imaging images of at least three of the measurement and reference targets and the target units, which are arranged at different positions in space, on the image acquisition unit, the images of the measurement and reference targets and of the target units each being arranged on separate image areas be directed to the image capture surface. This prevents the images of the targets from falling together on one image area, which would mean that the images would first have to be assigned to the respective target before the evaluation. The image pickup unit includes an image pickup surface having a first image area for capturing an image of the target units, a second image area for capturing an image of the target, and a third image area for capturing an image of the reference target. With such an image pickup unit, it is possible to simultaneously record images of three different targets. The mapping of the three targets to be measured by the measuring unit on separate image areas of the image recording surface of the image recording unit enables rapid evaluation of the images of the targets.

The measurement targets are, for example, plates on which target features are mounted in a specific arrangement. These target features can be arranged in any shape, number and arrangement on the target and form the geometry of the target. The measuring targets are fixed in a known position, for example via an adapter to a wheel. The reference targets are attached to the measuring units in such a way that they are visible from the respective measuring unit positioned on the other side of the vehicle.

The external device may be, for example, a calibration board on which geometric elements are applied, which are detected by the optical detection devices on the vehicle and used for their calibration. At least one target unit is attached to the external device. Such a target unit may, for example, correspond to a measurement target described above. It is also conceivable to attach a plurality of target units to the external device. Furthermore, the wheels on which the measurement targets are mounted may be the wheels of the front axle. In such an arrangement of the measurement targets, the external device is aligned with respect to the front axle of the motor vehicle.

The images of the measurement and reference targets are evaluated by the evaluation device, by using reference images of the measurement and reference targets and the

Target unit to be compared. These reference images consist of images of the measurement and reference targets and the target units, which were recorded at known angles and at known intervals and stored in the evaluation device. By comparing the recorded images with the reference images, the orientation and the position of the measurement targets and the target units and thus also the wheels and the external device relative to the measuring unit can be determined. to

Calculation of the orientation of the target units relative to the wheels, ie to the measurement targets on the right and the left wheel, the position of the left measurement unit must be be known relative to the right unit of measurement. This is determined by the evaluation of the images of the reference targets attached to the measuring units.

In a first embodiment, the left and right target units together form a target unit, thereby reducing the number of components on the external device. The one target unit is mounted centrally, for example, on the upper edge of the external device, so that it can be detected by the left and the right measuring unit.

In a further exemplary embodiment, the reference targets are each punctiform, in particular in the form of an LED, and the distance of the measuring units in the vehicle transverse direction is known. In addition, each measuring unit has a tilt sensor. The evaluation device is designed such that it determines the position of the external device, thereby comparing the images of the reference targets with reference images to determine the position of the measuring units, the known distance of the measuring units in the vehicle transverse direction and the inclination of the two measuring units. A point reference reference represents a very simple and inexpensive form of a reference target, with its use, the additional determination of the inclination of the measuring unit and the knowledge of the distance of the measuring units in the vehicle transverse direction is necessary to determine the position of the measuring units to each other.

In a further exemplary embodiment, the reference targets are in each case designed as at least two light points arranged in a line, in particular LEDs, with a predetermined spacing, and each of the measuring units has an inclination sensor. Such a reference target is a 2D target with which the distance as well as the angular displacement of the measuring units relative to one another can be determined by comparison with reference images of the reference targets. For the calculation of the position of the external device by the evaluation unit, when using such a 2D target, only the inclination of the inclination sensor determined by the inclination sensor is

Measuring units necessary, but not the previously determined distance of the measuring units in the vehicle transverse direction to each other.

In a further exemplary embodiment, the reference targets are in the form of a plurality of light spots, in particular LEDs, in a surface with respectively predetermined distances from one another or as light points present in different areas and planes, in particular LEDs formed. Such a reference target represents a 3D target. When using a 3D target, it is possible, the orientation in space, ie the angular displacement and the distances in vehicle longitudinal and transverse directions and the inclination of the measuring units to each other by comparing with a Reference image to determine, without the need for an additional inclination sensor or the knowledge of the distance of the measuring units to each other is required.

In addition, in another embodiment, at least one of

Measurement units provided a motion sensor, which, when it detects a movement of at least one of the measuring units, a picture of the measuring and

Target targets and the target unit by the image recording units triggers. Such a motion sensor may for example consist of a pendulum, wherein a movement of one of the measuring units results in a deflection of the pendulum. This ensures that, as soon as the position of the measuring units relative to each other or to the measurement targets and the target unit changes, this is newly determined by image acquisition of the measurement and reference targets and the target unit and thus the calculation of the position of the external device always the current Stand correspond. It is also conceivable that the motion sensor detects a movement of at least one of the measuring or reference targets or the at least one target unit or a movement of the motor vehicle and then triggers an image acquisition. It is thereby achieved that a change in the position of the measuring or reference targets or of the target unit or of the motor vehicle results in a new determination of the position of the external device from current image recordings of the measuring and reference targets and of the target unit.

In a further exemplary embodiment, the image recording units and the evaluation unit are designed for periodic or continuous image acquisition of the measurement and reference targets, which ensures that the position of the measurement units relative to one another is regularly updated.

In another embodiment, the optical device is a prism, a beam splitter, a mirror, a lens or a combination of these elements, with which images of the measurement and reference targets and the

Target unit can be imaged on the designated image areas of the image acquisition unit. The invention further relates to a measuring station with a motor vehicle standing thereon, on whose two opposite wheels in the transverse direction of the motor vehicle measuring targets are mounted, and with an external device positioned on the measuring station. The measuring station according to the invention further comprises a device for positioning an external device of the type described above.

The invention further comprises a method for positioning an external device according to the independent method claim. Such a method realizes the advantages described above, and all embodiments described with respect to the device and the advantages associated with them apply in procedural correspondence.

The invention is explained in more detail below with reference to several embodiments with reference to the accompanying figures.

1 shows a schematic representation of a measuring station with two target units, with a device for positioning an external device with respect to a motor vehicle and with a measuring target attached to two of the wheels of a motor vehicle according to an embodiment of the invention;

2 shows a schematic representation of a measuring station with an external device, with a device for positioning an external device with respect to a motor vehicle and with a measuring target attached to two of the wheels of a motor vehicle according to an exemplary embodiment of the invention;

3 is a schematic diagram of three image pickup surface areas of an image pickup unit of the apparatus for positioning an external device with respect to a motor vehicle of FIG. 1; and

4 shows a schematic representation of a measuring station with a target unit, with a device for positioning an external device with respect to a motor vehicle and with a measuring target attached to two of the wheels of a motor vehicle according to a further exemplary embodiment of the invention.

In Fig. 1, a measuring station 2 with two target units 14, 16, with a device for positioning an external device with respect to a motor vehicle and with two of the wheels 4, 6 of a motor vehicle mounted measuring targets 8, 10 shown schematically. For reasons of clarity, only the two wheels 4, 6 are shown in FIG. 1 of the motor vehicle. The device for positioning an external device consists of a left and a right measuring unit 18, 20, which are opposite to each other with respect to the not shown extended longitudinal axis of the motor vehicle. The measuring station shown in Fig. 1 is substantially symmetrical to the extended longitudinal axis of the motor vehicle, which is why the structure is first described by way of example with reference to the left side of the motor vehicle.

In the example illustrated in FIG. 1, the left measuring unit 18 is arranged centrally between the left motor vehicle wheel 4 and the left target unit 14 on a left side of the motor vehicle. The left measuring device 18 includes a left optical device 22 and a left image pickup unit 38. Further, located on the left side of the motor vehicle on the wheel 4, a left measuring target 8 and a target unit 14, which is arranged on the left side of the vehicle so that it Messtarget 8 relative to a horizontal opposite. The measuring target 8 is mounted at the height of the central axis of the wheel 4 via an adapter to the latter such that it protrudes in the axial direction to the left and is within the field of view of the left-hand measuring unit 18.

The target unit 14 is attached to an external device, not shown here, for example, a calibration board. On the left-hand measuring unit 18, there is also a left-hand reference target 12, attached by way of example above on the right-hand side of the measuring unit 18. Such a reference target 12 can be, for example, a single LED or several LEDs mounted in a known position on the measuring unit 18.

The left optical device 22 is arranged in a right region of the measuring unit 18 and centrally between the left measuring target 8 and the left target unit 14. Left behind the optical device 22, the image pickup unit 38 is arranged. Furthermore, optical light paths represented by arrows are shown in FIG. 1. One

Optical path 46 extends from the left target unit 14 to the left optical device 22, and an optical path 24 extends from the left measuring target 8 to the left optical device 22. Also shown is an optical light path 26 from the opposite reference target 44 toward the left optical device 22 extends. The left optical device 22 directs the light paths 24, 26 and the light path 46 to a common light path 28, which is shown in Fig. 1 in the form of three arrows, the on the left image pickup unit 38 impinges. As a result, images of the measurement target 8, the target unit 14 and the reference target 44 are imaged on the image recording surface of the left image acquisition unit 38. On the right side of the measuring station 2, arranged symmetrically to the described left side of the measuring station 2, are a right measuring unit 20, a right optical device 30, a right image pickup unit 40 and a right reference target 44, a right target unit 16 and a measuring target 10 arranged on the right-hand wheel 6. According to the left-hand measuring-station side described above, the right-hand optical device 30 from the right-hand measuring target 10 is the right-hand one

Target unit 16 and coming from the left reference target 12 light paths 32, 34, 48 which are directed by the right optical device 30 as a common light path 36 on the image pickup surface of the right image pickup device 40. FIG. 1 further shows an evaluation device 42, which is connected to the left image acquisition unit 38 and the right image acquisition unit 40 via a cable.

2 shows a schematic illustration of a measuring station 52 with an external device 50, with a device for positioning the external device 50 relative to a motor vehicle and with a measuring target 8, 10 attached to two of the wheels 4, 6 of a motor vehicle right measuring unit 18, 20 and the measuring targets 8, 10 and the target units 14, 16 are shown in more detail. In contrast to FIG. 1, in FIG. 2, for reasons of simplification, the evaluation device 42, the reference targets 12, 44 and the optical light paths 24, 26, 32, 34, 46, 48 are not shown.

In Fig. 2, the measuring targets 8, 10 and the target units 14, 16 are shown enlarged. Each measuring target 8, 10 consists of a substantially square plate whose horizontal center line is parallel to the respective vehicle wheel axis. On the targets 8, 10, 14, 16 are arranged in a certain pattern, circular optical

Target Features 68. As an example, ten such target features 68 arranged in the same pattern are shown on the measurement targets 8, 10 and the target units 14, 16. The target features 68 are arranged symmetrically to a vertical centerline of the targets 8, 10, 14, 16. FIG. 2 also shows that the plate-shaped measuring targets 8, 10 are arranged at an angle of, for example, 30 ° to the motor vehicle contact surface. In FIG. 2, furthermore, the external device 50 is shown in the form of a rectangular plate, on the sides of which the target units 14, 16 are attached via a mounting frame in such a way that they each face a measuring target 8, 10 of the motor vehicle wheels 4, 6. However, the target units 14, 16 can be arranged at any conceivable position on the external device, as long as they are detectable by the measuring units 18, 20.

In the left and right measuring units 18, 20 of FIG. 2, a mirror arrangement 56, 58 and an image recording unit in the form of a camera 60, 62 are respectively shown. The mirror assembly 56, 58 comprises two mirrors, which are exemplarily at right angles to each other, the front of the two mirrors at an angle of 45 ° to the vertical in the vehicle transverse direction and the rear of the two mirrors of a mirror assembly 56, 58 at an angle of -. 45 ° to the vertical in the vehicle transverse direction. In the embodiment in Fig. 2, the mirrors have a small distance from each other and do not touch. The cameras 60, 62 are aligned with the mirror arrangements 56, 58 of the respective measuring devices 18, 20, so that the light paths deflected from the front and from the rear towards the side by the mirror arrangements 56, 58 impinge on the cameras 60, 62 and are picked up there can be.

Three examples of an image-receiving surface 72, 80, 88 are shown in FIG. The upper image pickup surface 72 has a rectangular shape that is divided into three rectangular image areas 74, 76, 78. The first and second image areas 74, 76 divide an upper portion of the image pickup surface 72 at the vertical centerline into two equally sized image areas 74, 76 and occupy approximately three quarters of the total image pickup surface 72. The third image area 78 comprises a horizontal lower longitudinal stripe of approximately one quarter of the image recording surface 72. Illustratively, images of the target features 68 of the measurement and reference targets 8, 10, 12, 44 and the target units 14, 16 are shown on the image areas 74, 76, 78 wherein the images on the first image area 74 correspond to the ten target features 68 of the target units 14, 16 and the images on the second image area 76 correspond to those of an associated measurement target 8, 10. On the third image area 78, an image of the reference target 12, 44 is imaged with its target features 68 on the left and right edges of the third image area 78. In the further exemplary embodiments of image recording surfaces 80, 88 illustrated in FIG. 3, the images of the target features 68 are not shown for the sake of simplicity. The image pickup surface 80 of FIG. 3 is vertically subdivided into three image areas 82, 84, 86. The first and second image areas 82, 84 are the same size and located at the outer right edge and outer left edge of the image pickup surface 80, respectively. Between the first and second image areas 82, 84 is the third image area 86, which is about one quarter Imaging surface 80 includes. Furthermore, FIG. 3 shows an image recording surface 88, which is subdivided into three image regions 90, 92, 94, wherein the third image region 94 is circular and lies in the center of the image recording surface 88. The first image area 90 forms the left side and the second one

Image area 92, the right side of the image pickup surface, wherein the first and the second image area 90, 92 are the same size and symmetrical to each other.

Fig. 4 shows a measuring station 93 with all elements of Fig. 1, instead of two target units 14, 16 only one target unit 102 is shown at the level of the elongated longitudinal axis of the motor vehicle and in addition to the measuring units 18 and 20 each have a tilt sensor 94, 98 and a motion sensor 96, 100 is arranged. The left tilt sensor 94 is located in the lower left area of the measuring unit 18, and right next to it, the left motion sensor 96 is arranged. The tilt and motion sensors 94, 96, 98, 100 of each measuring unit 18, 20 are in addition to the

Evaluation device 42 connected. Furthermore, FIG. 4 shows that of the

Target unit 102 on the optical devices 22, 30 of the measuring units 18, 20 directed light paths 104, 106, which are transmitted from the optical devices 30, 22 to the image pickup devices 38, 40.

The mode of operation of the device for positioning an external device with respect to a motor vehicle is explained below by way of example with reference to the left-hand motor vehicle side with the aid of the left-hand measuring unit 18. The optical device 22 directs the light paths from the measurement and reference targets 8,

In the embodiment shown in Figures 1 and 2, the light path 46 is deflected by the target unit 14 through the upper mirror of the mirror assembly 56 at an angle of 90 ° in the direction of the image pickup unit 60, and the light path 24 from the left measuring target 8 is deflected by the rear mirror of the mirror assembly 56 at an angle of 90 ° in the direction of the image pickup unit 60. The light path from the reference target 44 is not deflected in the exemplary mirror assembly 56 in FIG. The light paths 24, 26, 46 impinge on the image recording unit 38, wherein, as shown in FIG. 3, the light path 46 from the target unit 14 is an image on the first image area 74, the light path 24 of the left measuring target 8 is an image on the second image area 76 and the light path 26 of the reference target 44 generates an image on the third image area 78 of the image pickup unit 46. The shape of the regions 74, 76, 78 depends on the mirror assembly 56. The images captured by the image recording unit 38 are then evaluated by the evaluation device 42 in order to calculate the orientation of the wheel 4 and the target unit 14 relative to the left-hand measuring unit 18. In the same way, to calculate the orientation of the wheel 6 and the target unit 16 of the right side of the motor vehicle, the images of the measurement and reference targets 10, 12 and the target unit 16 are detected by the right image acquisition unit 40 and analyzed by the evaluation device 42.

For evaluation, the evaluation device 42 compares the image regions 74, 76, 78 of the image recording units 38, 40 with reference data. These reference data include images of the measurement and reference targets, which were recorded at a known angle and a known propriety and are stored in the evaluation. The orientation of the wheel 4 and the left side target unit 14 is determined by the evaluator 42 by displaying the images of the left measurement target 8 and the left

Target unit 14 and their optical target features 68 on the first and second image area 74, 76 with reference images of the measuring target 8 and the target unit 14 are compared. In the same manner, the orientation of the right measurement target 10 and the right target unit 16 relative to the right measurement unit 20 is determined. In order to determine the position of the left measuring target 8 and the left target unit 14 relative to the right measuring target 10 and the right target unit 16, the position and orientation of the left measuring unit 22 relative to the right measuring unit 24 is determined. This is determined by the evaluation of the image reference targets 12, 44 on the image areas 78, 86, 94 of the image acquisition unit 38, 40.

The determination of the orientation of the measuring units 18, 20 relative to one another can be carried out in various ways, which depend on the type of the respective reference targets 12, 44. The reference target 12, 44 may for example be point-shaped, ie consist of a single LED, which requires that for determining the relative position of the measuring units 18, 20 to each other, the distance of these in the vehicle transverse direction each other known and stored in the evaluation device 42, and that on Each of the measuring units 18, 20, a tilt sensor 94, 98 is present, which is connected to the evaluation device 42 and determines the inclination of the respective measuring unit 18, 20, as shown with reference to the reference numerals 94 and 96 in Figure 4. The image of the reference target 12, 44 made of an LED on the associated image area 78, 86, 94 of the image recording surface can then be used by the

Evaluation device, the orientation of the measuring units 18, 20 are determined in the vehicle longitudinal direction relative to each other.

If the reference target 12, 44 consists of a two-dimensional target, the position of the measuring units relative to one another, ie the distance and the angular displacement of the measuring units, can be calculated from the comparison of the image of the 2D target with a reference image. This requires that a tilt sensor 94, 98, which is connected to the evaluation device 42 and determines the inclination of the respective measuring unit 18, 20, be provided on each of the measuring units 18, 20, as described with reference to the reference symbols 94 and 96 is shown in FIG. The distance between the two measuring units 18, 20 to each other need not be known.

A three-dimensional target with a known arrangement of optical

Target features 68 for determining the position of the measuring units 18, 20 relative to each other neither a tilt sensor 94, 98 nor the knowledge of the distance of the

Measuring units 18, 20 in the vehicle transverse direction.

The calculation of the orientation of the measuring units 18, 20 relative to one another can be continuously updated, which can be carried out in various ways. As shown in FIG. 4, a motion sensor 96, 100 may additionally be provided in each of the measuring units 18, 20, which detects a movement of the respective measuring units 18, 20 and thereupon takes a picture of the measuring targets 8, 10,

Target units 14, 16 and the reference targets 12, 44 triggers, which are then evaluated by the evaluation device 42

A periodic or continuous updating of the measured data is also possible. In this case, an image recording of the measurement targets, 8, 10, the target units 14, 16 and reference targets 12, 44 is performed at predetermined time intervals, and these data are evaluated by the evaluation device 42. Further, the optical data of the reference targets 12, 44 may be continuously monitored to be changed once a change is detected in the data to recalculate the position of the measuring units 18, 20 relative to each other.

Claims

claims

1 . Device for positioning an external device (50), in particular a calibration device of a cruise control system or of a lane departure warning device, with respect to a motor vehicle, comprising:

 a left measuring unit (18) for positioning on a left side of the motor vehicle such that a measuring target (8) on a left wheel (4) of the motor vehicle and a left target unit (14) of the external device (50) from the left measuring unit

(18) are recordable; and

 a right measuring unit (20) for positioning on a right vehicle side such that a measuring target (10) on a right wheel (6) of the motor vehicle and a right target unit (16) of the external device (50) from the right measuring unit (20 ) are detectable from;

 each of the two measuring units comprising:

 a reference target (12, 44) visible from the respective other measuring unit (18, 20);

 an image pickup unit (38, 40) whose image pickup surface (72, 80, 88) has a first image area (74, 82, 90) for capturing an image of the image

Measuring targets on the motor vehicle wheel (4, 6), a second image area (76, 84, 92) for capturing an image of the target units (14, 16) of the external device (50) and a third image area (78, 86, 94) for detecting an image of the reference target (12, 44); and

 an optical device (22, 30) which is arranged and designed such that an image of the measuring target (8, 10) of the motor vehicle wheel on the first image area (74, 82, 90), an image of the target units (14, 16) of external means (50) on the second image area (76, 84, 92) and an image of the reference target (12, 44) on the third image area (78, 86, 94) is obtained;

 an evaluation device (42), which is designed to detect from the images of the measurement targets (8, 8, 8, 8, 9, 8, 9, 8, 9, 9, 8) of the two measuring units (18, 20) by the image regions (74, 76, 78, 82, 84, 90, 92). 10) of the vehicle wheels, the target units (14, 16) of the external device (50) and the reference targets (12, 44) by comparison with reference images of the measurement targets (8, 10) and the target units (14, 16)

Determine position of the external device (50) to the motor vehicle.

The apparatus of claim 1, wherein the left and right target units (14, 16) together form a single target unit (102).

3. Apparatus according to claim 1 or 2,

 wherein the reference targets (12, 44) are each punctiform, in particular in the form of an LED,

 each measuring unit (18, 20) having a tilt sensor (94, 98), and

 wherein the evaluation device (42) is designed such that it uses the inclination of the two measuring units (18, 20) and the known distance of the measuring units (18, 20) in the vehicle transverse direction for determining the position of the external device (50).

4. Apparatus according to claim 1 or 2,

 wherein the reference targets (12, 44) are each formed as at least two light points arranged in a line, in particular LEDs, with a predetermined distance, and

 wherein each measuring unit (18, 20) has an inclination sensor (94, 98), and wherein the evaluation device (42) is designed such that it can be selected from the images of the reference targets (12, 44) acquired by the image recording units (38, 40). compared with reference images of the reference targets (12, 44) determines the distance and the angular displacement of the measuring units (18, 20) to each other, and the distance in the vehicle transverse direction and the angular displacement of the measuring units (18, 20) and the inclination of the two measuring units ( 18, 20) in determining the position of the external device (50).

5. Apparatus according to claim 1 or 2,

 wherein the reference targets (12, 44) are formed as a plurality of light spots, in particular LEDs, in a surface with respectively predetermined distances from one another or as light points present in different areas and planes, in particular LEDs, and

wherein the evaluation device (42) is adapted to receive the distance and the angular displacement from the images of the reference targets (12, 44) received on the image recording units (72, 80, 88) in comparison with reference images of the reference targets (12, 44) the measuring units (18, 20) to each other and determining the inclination of the two measuring units (18, 20), and the distance and the angular displacement of the measuring units (18, 20) and the inclination of the two measuring units (18, 20) in determining the position of the external device (50) ,

6. Device according to one of the preceding claims, wherein at least one of the measuring units (18, 20), a motion sensor (96, 100) is provided, which, when he detected a movement of at least one of the measuring units (18, 20), a Imaging of the measuring and reference targets (8, 10, 12, 44) and the target unit (14, 16, 102) by the image recording units (38, 40) triggers.

7. Device according to one of the preceding claims,

 wherein the image recording units (38, 40) and the evaluation unit (42) for a periodic or continuous image acquisition of the measuring and reference targets (8, 10, 12, 44) and the target unit (14, 16, 102) are formed.

8. Device according to one of the preceding claims,

 wherein the optical device (22, 30) is a prism, a beam splitter, a mirror, a lens, or a combination of these elements.

9. Measuring station with a motor vehicle standing thereon and with an external device (50) positioned on the measuring station, wherein measuring targets (8, 10) are mounted on two wheels (4, 6) of the motor vehicle opposite the motor vehicle transverse direction, and with a device for positioning external device (50), in particular a calibration device of a cruise control system or of a lane departure warning device with respect to a motor vehicle, according to one of the preceding claims,

 wherein the left measuring unit (18) is positioned on the left side of the motor vehicle such that the measuring target (8) on the left vehicle wheel (4) and a left target unit (14) of the external device (50) are visible from the left measuring unit (18) are; and

wherein the right measuring unit (20) is positioned on the right side of the vehicle such that the measuring target (10) on the right vehicle wheel (6) and a right target unit (16) of the external device (50) are detectable from the right measuring unit (20) are.

10. A method for positioning an external device (50), in particular a calibration device of a cruise control system or a lane departure warning system, with respect to a motor vehicle, comprising:

 Attaching Messtargets (8, 10) on two opposite in the vehicle transverse direction wheels (4, 6) of a motor vehicle;

 Positioning the external device (50) in front of or behind the motor vehicle; Positioning a left measuring unit on the left side of the motor vehicle such that the measurement target on the left vehicle wheel (4) and a left

Target unit (14) of the external device (50) from the left-hand measuring unit (18) are detectable, wherein the left-hand measuring unit (18) visible from the right measuring unit (20) reference target (12), an optical device (22) and a Imaging unit (38) has;

 Positioning a right-hand measuring unit (20) on the right-hand motor vehicle side such that the measuring target (10) on the right-hand motor vehicle wheel (6) and a right-hand target unit (16) of the external device (50) can be detected by the right-hand measuring unit (20), wherein the right measuring unit (20) has a reference target (44) visible from the left measuring unit, an optical device (30) and an image pickup unit (40);

 Generating, by the optical means (22) of the left measuring unit (18), a

Image of the measurement target (8) of the left-hand vehicle wheel (4) on a first image area (74, 82, 90), an image of the target units (14, 16) on a second image area (76, 84, 92) and an image of the reference target (8). 12, 44) on a third image area (78, 86, 94), and capturing these images by the image acquisition unit (38) of the left measurement unit;

 Generating, by the optical device (30) of the right-hand measuring unit (20), an image of the measuring target (10) of the right-hand vehicle wheel on a first image area (74, 82, 90) of an image of the target units (14, 16) on a second one Image area (76, 84, 92) and an image of the reference target (12, 44) on a third image area (78, 86, 94), and capturing these images by the image capturing unit (40) of the right measurement unit (20);

 Determining the position of the external device (50) relative to the motor vehicle from the images of the measurement targets (8, 10, 10) received on the image regions (74, 76, 78, 82, 84, 90, 92, 94) of the two measurement units (18, 20) ) of the vehicle wheels (4, 6), the target unit (14, 16) of the external device (50) and the reference targets

(12, 44) by comparison with reference images of the measurement targets (8, 10) to the force vehicle wheels, the target units (14, 16) of the external device (50) and the reference targets (12, 44).