DE102020213976A1 - Method and system for determining the attitude of a vehicle in preparation for sensor calibration - Google Patents

Abstract

A method for determining the position of a vehicle in preparation for a sensor calibration is proposed, the method comprising the steps of providing the vehicle in a calibration room, arranging marking elements at predetermined positions of the vehicle, determining a center line on or on the vehicle, detecting of positions of the marking elements arranged on the vehicle by spatially fixed optical detection units in a spatially fixed coordinate system, calculating a position and alignment of a vehicle-fixed coordinate system in the spatially fixed coordinate system on the basis of the center line and the detected positions of the marking elements, retrieving positions of vehicle sensors in the vehicle-fixed Coordinate system from a storage unit, and calculating positions and orientations of the vehicle sensors in the spatially fixed coordinate system.

Description

The present invention relates to a method and a system for determining the attitude of a vehicle in preparation for sensor calibration.

State of the art

Modern motor vehicles often have a number of sensors that support the driver in recognizing the surroundings. For example, the use of cameras, a radar system, a LIDAR system, distance sensors or the like that are assigned to a driver assistance system is known. It is common for sensors with a more or less directional detection area to be calibrated in order to ensure correct functioning. The calibration can take place during final assembly or shortly before delivery of the vehicle, as well as during repair or maintenance of the vehicle.

It is known to calibrate such directional sensors of a vehicle by positioning a calibration device in a specific orientation relative to the vehicle to which the sensor is attached and testing the behavior of the sensor. If the behavior of the sensor is inaccurate, its alignment is changed and a new check is carried out. The calibration process requires the reference objects to be placed very precisely in order to achieve a repeatable, accurate result. Since the vehicles are moved on their own wheels prior to a calibration and are never in exactly the same position, the reference objects must be placed for each vehicle, which is complex and therefore cost-intensive.

Disclosure of Invention

It is consequently an object of the invention to provide an improved method for supporting the determination of necessary positions for reference objects for the calibration of vehicle sensors.

The object is achieved by a method having the features of independent claim 1. Advantageous developments can be found in the subclaims and the following description.

A method for determining the position of a vehicle in preparation for a sensor calibration is proposed, the method comprising the steps of providing the vehicle in a calibration room, arranging marking elements at predetermined positions of the vehicle, determining a center line on or on the vehicle, Detection of positions of the marking elements arranged on the vehicle by spatially fixed optical detection units in a spatially fixed coordinate system, calculating a position and alignment of a vehicle-fixed coordinate system in the spatially fixed coordinate system on the basis of the center line and the detected positions of the marking elements, retrieving positions of vehicle sensors in the vehicle-fixed coordinate system from a memory unit, and the calculation of positions and orientations of the vehicle sensors in the spatially fixed coordinate system.

The calibration space is to be regarded as a spatially limited area whose dimensioning is sufficient to place reference objects at predetermined positions relative to the vehicle sensors for calibrating the vehicle sensors of a vehicle located in the calibration space. A spatially fixed coordinate system is provided in the calibration space, which has a fixed alignment. At the beginning of the method according to the invention, the vehicle is placed in the calibration room.

The vehicle-fixed coordinate system is a Cartesian, right-handed coordinate system, which has its origin, for example, in a center point of the rear axle of the vehicle. The alignment of the vehicle can be determined by the position of the origin of the vehicle-fixed coordinate system in the spatially fixed coordinate system and three orientation angles, i.e. the Euler angles. These are known as yaw, pitch and roll angles.

The marking elements are devices that can be positioned on the vehicle and are optically clearly recognizable. For example, the marking elements can be designed as flags, signs or plates that are provided with a marking. The marking could be designed as a pattern that makes at least one specific point on the marking element recognizable. The marking elements are particularly preferably designed in such a way that there is a pattern on them which makes a spatial orientation of the marking elements recognizable. This can include a lattice structure or a chessboard structure, for example, which is arranged on a flat base body. Depending on the alignment of the flat base body relative to an optical detection unit, a perspective distortion can be seen, from which an alignment can be determined.

The center line of the vehicle can be determined by different measures. On the one hand, it is conceivable for the optical detection units to optically detect the vehicle from different directions in order to then enable a processor unit or the like to calculate a center line on the basis of the detection. On the other hand, it is conceivable to use a laser line projector, which is arranged in the calibration space and is designed to emit laser beams in one plane. The plane is preferably adjustable and extends in the xz direction of the vehicle, ie through a longitudinal axis and vertical axis of the vehicle. This can be adjusted manually or automatically so that the laser line extends along the central or longitudinal axis of the vehicle.

Depending on the requirements, the optical detection units are arranged at different points within the calibration space and have known positions in the spatially fixed coordinate system. They are designed to detect at least the marking elements, so that at least the distances between the optical detection units and the marking elements can be determined from this by using an image processing process. The spatial relative positions between the optical detection units and the marking elements could also be determined from the synopsis of all detection data of the optical detection units. The absolute positions of the marking elements in the spatial coordinate system can be calculated from the knowledge of the spatial positions of the optical detection units. Depending on the use of the marking elements, alignments of the marking elements, for example an angle around a vertical axis in the spatially fixed coordinate system, can also be determined.

From the knowledge of the absolute positions and possibly the alignments of the marking elements and the center line, a position and alignment of a vehicle-fixed coordinate system in the spatially fixed coordinate system can consequently be determined. In order to calibrate the vehicle sensors, it is necessary to place reference objects in specific relative positions that depend on the installation location of the relevant vehicle sensors and thus on positions in the vehicle-fixed coordinate system. Since the relation between the vehicle-fixed coordinate system and the spatially fixed coordinate system is known due to the previous method steps, installation positions of the vehicle sensors can be retrieved from a storage unit in order to then transform them into the spatially fixed coordinate system. The installation positions originate, for example, from a CAD system that includes data representing the structure of the vehicle. This simplifies the determination of the spatial position of the reference objects, which could, for example, be moved automatically in the calibration space to the transformed positions in the spatially fixed coordinate system.

In an advantageous embodiment, necessary reference object positions are determined in the spatially fixed coordinate system to prepare for the calibration of the vehicle sensors, as already explained above. This can be done, for example, by retrieving prescribed relative positions from a vehicle-specific database and transforming the relative positions into the spatially fixed coordinate system.

The orientation of the vehicle-fixed coordinate system can include at least one of a roll angle, a pitch angle and a yaw angle. Based on the knowledge of the origin of the vehicle-fixed coordinate system, the roll angle, the inclination angle and/or the yaw angle can be used to determine where and with what orientation the vehicle is located in the spatially fixed coordinate system. With knowledge of all three angles and also the origin of the vehicle-fixed coordinate system, all six degrees of freedom can be determined. The roll or roll angle and the angle of inclination can be determined, for example, by detecting all the centers of all marking elements, if they are located on the wheel hubs, to create a plane. The location of this plane is characterized by these angles and a distance from a ground.

The method according to the invention may further include the step of tilting the vehicle to raise one side of the vehicle prior to detecting the positions of the markers. Especially when calibrating radar sensors, it is known that radar sensors with a low installation height are often difficult to calibrate due to reflections on the ground. This can be counteracted by tilting the vehicle sufficiently to lift the side of the vehicle in question. This makes sense in particular when the calibration of a radar sensor arranged on a vehicle corner is to be achieved with a low installation height.

The marking elements are preferably arranged on the wheels of the vehicle. The marking elements can be arranged in particular on wheel hubs. This means that they are located at a center point of the wheel in question. Consequently, the marking element at least partially intersects a wheel axle of the wheel. There are However, other positions are also conceivable. By arranging the markers on the four wheels, or at least on the wheels of one axle or one side of the vehicle, the markers can be placed in precisely a priori known positions determined by the structure of the vehicle. It is advantageous if the marking elements extend at least partially along the wheel axle of the wheel in question. Marking elements could consequently lie on a plane which is perpendicular to a plane formed by the outer surface of the wheel. The optical detection units arranged outside the vehicle can then easily detect the marking elements and precisely determine a position of the marking elements that is dependent on the orientation of the wheels.

The x-axis or the longitudinal axis of the vehicle can be determined from the center line, for example by aligning the laser line projector. The position of a y-axis or a transverse axis can be determined by detecting the center points of the marking elements of the wheels of an axis and forming a connecting line. The vertical axis can be calculated from the intersection of the vehicle's longitudinal axis, the transverse axis and a surface normal to a plane through all the centers of the wheel-mounted marking elements. The thrust angle is an average of the yaw angles of both markers on the rear wheels, for example.

The optical detection units could preferably detect the orientation of a laser line projector by scanning a marking element arranged thereon, the laser line projector emitting laser beams in a plane intersecting the center line of the vehicle. This supports the determination of the center point of the vehicle-fixed coordinate system. Since the laser line from the laser line projector intersects the origin of the vehicle-fixed coordinate system, the origin can be clearly determined in conjunction with the positions of at least one or two marking elements. In order for the laser beams to pass through the centerline, a user can manually adjust the laser line projector based on features on the vehicle's centerline.

In a particularly advantageous embodiment, the marking elements can be pivotably arranged so that they are aligned with the force of gravity, with a vertical axis of the spatially fixed coordinate system running parallel to the direction of gravity. Consequently, the marking elements are always aligned parallel to the direction of gravity. A direction of extent of the marking elements is thus known in each case and the detection of an alignment or orientation of the marking elements is thereby considerably simplified.

In this context, it is particularly useful that the marking elements have a pivot axis that coincides with a wheel axle, for example.

The method may further include detecting wheel contours and/or wheel housing contours to support calculating the location and orientation of the vehicle-fixed coordinate system in the spatially-fixed coordinate system. The position of a wheel relative to the rest of the vehicle is not fixed, since the wheels of a vehicle are usually spring-mounted and their distance from a wheel house can always change. It therefore makes sense to detect wheel contours and/or contours of wheel housings in order to support the calculation of the position and orientation of the coordinate system fixed on the vehicle. Since the contours of wheels and wheel housings are clearly specified and very easy to identify visually, it makes sense to use these contours for additional support. Based on the detection of the contours of the wheel and the wheel housing, their distance from one another can be determined. As an alternative to this, however, the method can, if it is executed on a processor unit, a computer or the like, provide the input option for entering a manually determined distance between the wheel hub and the wheel housing.

The invention also relates to a system for determining the position of a vehicle in a calibration space in preparation for a sensor calibration, having a plurality of marking elements for arranging at predetermined positions on the vehicle, a plurality of optical detection units to be arranged in a spatially fixed manner, and a processor unit that can be connected to the optical detection units, the processor unit being is designed to determine a position and alignment of a vehicle-fixed coordinate system in a spatially-fixed coordinate system on the basis of the orientation of a determined center line of the vehicle and positions of the marking elements that can be detected by the optical detection units, to retrieve positions of vehicle sensors in the vehicle-fixed coordinate system from a storage unit, and positions and To calculate alignments of the vehicle sensors in the spatially fixed coordinate system and to store them in preparation for a sensor calibration.

As explained above, the system according to the invention can have a laser line projector which is designed to emit a laser beam in a plane with an adjustable alignment in the spatially fixed coordinate system.

In a preferred embodiment, the system may further include a tilting device for tilting the vehicle in the calibration space. The tilting device allows the vehicle to be tilted about a specific axis in order to raise a desired side of the vehicle. As a result, the position of a radar sensor or other vehicle sensor can be influenced in order to improve a measurement of a reference object during sensor calibration.

Further measures improving the invention are presented in more detail below together with the description of the preferred exemplary embodiments of the invention with the aid of figures.

character list

• 1 eine schematische Darstellung des erfindungsgemäßen Verfahrens
• 2 ein erfindungsgemäßes System in einer räumlichen Darstellung
• 3 ein Detail des Systems
• 4 eine Draufsicht auf den Kalibrierungsraum
• 5 eine schematische Darstellung einer ermittelten Ebene in dem Fahrzeug
• 6 das erfindungsgemäße System mit geneigtem Fahrzeug

It shows:

• 1 a schematic representation of the method according to the invention
• 2 a system according to the invention in a spatial representation
• 3 a detail of the system
• 4 a top view of the calibration room
• 5 a schematic representation of a determined level in the vehicle
• 6 the tilted vehicle system of the present invention

1 shows a method 2 according to the invention for determining the position of a vehicle in preparation for a sensor calibration in a schematic, block-based representation. First, the vehicle is made available 4, for example driven into a calibration room. Then marking elements are arranged at predetermined positions of the vehicle 6, for example on the wheel hubs. A center line of the vehicle is determined 8. On the one hand, this can be done by arranging a laser projector in the calibration space, which emits a laser beam in a plane with an adjustable orientation. This plane can be manually or automatically adjusted to intersect features of the vehicle that are on its center line or a vertical center plane. This is marked here with step 8a. As an alternative to this, the center line can be determined by means of optical detection units via an image processing process, which is characterized by method step 8b. Then positions of the marking elements arranged on the vehicle are detected by spatially fixed optical detection units in a spatially fixed coordinate system 10 and a position and orientation of a vehicle-fixed coordinate system in the spatially fixed coordinate system is calculated on the basis of the determined center line and the detected positions of the marking elements 12. Positions of vehicle sensors in the Vehicle-fixed coordinate system are retrieved from a memory unit 14 and from this the positions and alignments of the vehicle sensors in the spatially fixed coordinate system are calculated 16.

2 12 shows a system 18 for determining the location of a vehicle 20 in a calibration space 22 in preparation for sensor calibration. Here, the vehicle 20 is placed in the calibration space 22 . A plurality of optical detection devices 24 are arranged spatially fixed, which are directed here, for example, from above onto the vehicle 20 and can detect this from different angles. By way of example, four optical detection units 24 are provided, which are arranged in the longitudinal direction at the front left, front right, rear left and rear right. A processor unit 19 is coupled to the optical detection units 24 and is designed to carry out the method described above. By way of example, it has a storage unit 21 which stores data on the installation positions of vehicle sensors to be calibrated, for example. The memory unit 21 can also be arranged outside the processor unit 19 .

A marking element 28 is arranged on the vehicle 20 on each wheel 26 . This is implemented as a plate-shaped or flat element with a checkerboard pattern, as shown in 3 shown in more detail. The marking elements are each placed on a wheel axle 30 of the relevant wheel 26 here. For example, they are designed in such a way that they are always aligned with the direction of gravity. To this end, they are mounted pivotably on the wheel axle 30 . To support the measurement, a distance d between the wheel axle 30 and a wheel housing can be measured in order to be able to compensate for any positional deviations between the individual wheels 26 and a chassis mounted on them. The measurements can be automated or manual.

In addition, a laser line projector 32 is provided, which is placed in front of the vehicle 20 and is designed to emit laser beams in a vertical plane. The laser line projector 32 can be adjusted manually so that the laser beam plane runs through a center line 34 of the vehicle 20 after a corresponding adjustment. By aligning the laser line projector 32, the orientation of the center line can be determined. For this purpose, the laser line projector 32 also has a marking element 28 which, for example perpendicular to the plane of the laser beam, thus allowing detection of the plane of the laser beam. To adjust the laser beam level, the laser line projector 32 can preferably be pivoted both about a vertical axis and moved along a transverse axis.

4 shows the calibration space 22 in a plan view. It can be seen here that the wheel axles 30 each coincide with a pivot axis of the marking elements 28 . This means that from the recognition of the positions of the marking elements 28, an orientation of a plane 36 (see 5 ) can be determined in space. A surface normal 38 can be generated on this plane 36 . The point of intersection of the surface normal 38 with the vehicle longitudinal axis (xv axis) and the vehicle transverse axis (yv axis) allows the determination of the vertical axis (zv axis) axis in the vehicle-fixed coordinate system. The y _v -axis can be determined by connecting centers 40 of two marking elements 28 which are arranged on wheels 26 of a rear axle 42 of vehicle 20 . A thrust angle is calculated as the mean yaw angle of the wheels 26 of the rear axle 42 by the marking elements 28 arranged thereon. Knowing the position and orientation of the xv, yv and zv axes of the vehicle 20 enables a transformation of positions from the vehicle-fixed coordinate system into a spatially fixed coordinate system, ie the xw, yw and zw axes.

Installation positions of individual vehicle sensors (not shown here) can therefore be transformed very easily into the spatially fixed coordinate system after being retrieved from the storage unit 21 . Consequently, predetermined relative positions of reference objects, which are to be placed relative to the individual vehicle sensors, can be transformed into spatially fixed coordinates. The method according to the invention and the system according to the invention, which executes the mentioned method, can consequently arrange reference objects precisely for a vehicle 20 placed anywhere in the calibration space 22 in order to carry out a calibration of all conceivable vehicle sensors which can be located at any installation positions.

6 12 shows the vehicle 20 having a pitch angle pV relative to a ground 48 as seen by the slanted plane 36. FIG. For this purpose, a tilting device 50 can be provided, which tilts the vehicle 20 in this way. It is also possible to use alternative tilting devices 50 that can be used to raise another side of the vehicle. The angle of inclination leads to a vehicle front 44 being raised, so that a vehicle sensor 46 arranged on the vehicle front 44 is at an increased distance from a floor 48 . As a result, reference objects could be placed at a greater distance from the floor 48 in order to be able to rule out possible reflections or other disruptive effects with the floor 48 during a calibration.

Claims (10)

Method (2) for determining the position of a vehicle in preparation for a sensor calibration, comprising the steps: - Providing (4) the vehicle (20) in a calibration room (22), - Arranging (6) of marking elements (28) at predetermined positions of the vehicle (20), - Determining (8) a center line (34) on or on the vehicle (20), - Detection (10) of positions of the marking elements (28) arranged on the vehicle (20) by spatially fixed optical detection units (24) in a spatially fixed coordinate system, - Calculating (12) a position and alignment of a vehicle-fixed coordinate system in the spatially fixed coordinate system based on the determined center line (34) and the detected positions of the marking elements (28), - retrieving (14) positions of vehicle sensors (46) in the vehicle-fixed coordinate system from a memory unit, and - Calculating (16) positions and orientations of the vehicle sensors (46) in the spatially fixed coordinate system in preparation for the sensor calibration. Method (2) according to claim 1 , further comprising the step: - determining necessary reference object positions in the spatially fixed coordinate system to prepare for the calibration of the vehicle sensors (46). Method (2) according to claim 1 or 2 , wherein the orientation of the vehicle-fixed coordinate system comprises at least one of a roll angle, a pitch angle and a yaw angle. Method (2) according to one of the preceding claims, further comprising the step: - Tilting the vehicle (20) to lift a vehicle side (44) before detecting the positions of the markers (28). Method (2) according to one of the preceding claims, in which the marking elements (28) are arranged on wheels (26) of the vehicle (20). A method (2) according to any one of the preceding claims, wherein the optical detectors are units (24) detect the orientation of a laser line projector (32) by scanning a marking element (28) arranged thereon, the laser line projector (32) emitting laser beams in a plane intersecting the center line (34) of the vehicle (20). Method (2) according to one of the preceding claims, wherein the marking elements (28) are pivotally arranged so that they align with gravity, and wherein a vertical axis (z _w ) of the spatially fixed coordinate system runs parallel to the direction of gravity. Method (2) according to one of the preceding claims, further comprising detecting wheel contours and/or contours of wheel housings to support the calculation of the position and orientation of the vehicle-fixed coordinate system in the spatially-fixed coordinate system. A system (18) for determining the location of a vehicle (20) in a calibration space (22) in preparation for sensor calibration, comprising: - a plurality of marking elements (28) for arranging at predetermined positions of the vehicle (20), - several spatially fixed to be arranged optical detection units (24), and - a processor unit (19) that can be connected to the optical detection units (24), the processor unit (19) being designed to determine a position and orientation of a coordinate system fixed on the vehicle in a coordinate system fixed in space on the basis of the orientation of a determined center line (34) of the vehicle (20 ) and to determine positions of the marking elements (28) that can be detected by the optical detection units (24), to retrieve positions of vehicle sensors (46) in the vehicle-fixed coordinate system from a storage unit (21), and positions and alignments of the vehicle sensors (46) in the spatially fixed coordinate system to be calculated and filed in preparation for a sensor calibration. System (18) according to claim 9 , further comprising a tilting device (50) for tilting the vehicle (20) in the calibration space (22).

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