DE102019118481A1 - Calibrating an active optical sensor system - Google Patents

Abstract

According to a method for calibrating an active optical sensor system (3), a point cloud (6) is generated by means of the active optical sensor system (3) and transformed into a reference coordinate system (x0 ', y0') by means of a computing unit (4). A reference angular position (δ0) of a virtual reference sensor system is determined by the computing unit (4) based on the transformed point cloud and an angular position (δs) of the sensor system (3) is determined by the computing unit (4) based on the reference angular position (δ0).

Description

The present invention relates to a method for calibrating an active optical sensor system, a point cloud of sampling points being generated by means of the active optical sensor system, each sampling point of the point cloud containing three spatial frame coordinates with respect to a sensor coordinate system. The invention also relates to a corresponding sensor device, a motor vehicle and a computer program.

Active optical sensor systems, such as lidar systems, can be mounted on motor vehicles in order to implement various functions of electronic vehicle guidance systems or driver assistance systems. These functions include distance measurements, distance control algorithms, lane keeping assistants, object tracking functions and so on. Deviations of an installation position and an installation orientation of the sensor system from a nominal orientation influence the accuracy of the measured values or their interpretation and evaluation and thus the reliability and robustness of the corresponding functions. It is therefore necessary to calibrate the active optical sensor system in order to be able to compensate for corresponding orientation or position deviations.

Known methods for calibrating active optical sensor systems use, for example, calibration templates or targets specially provided for this purpose in order to compare measured values of the sensor system with expected measured values. As a result, such calibration methods cannot be used online, that is to say while the sensor system is in use in normal operation of the motor vehicle. Changes in position or orientation of the sensor system, which occur in the course of the service life of the sensor system or the motor vehicle, cannot be taken into account in this way.

Online calibration methods which use excellent objects in an environment of the sensor system, which would be suitable as a calibration template, are conceivable, but would be limited to a predetermined target alignment of the sensor system.

Against this background, it is an object of the present invention to provide an improved concept for calibrating an active optical sensor system, which does not require a special calibration template and can also be used for any desired orientation of the sensor system.

According to the invention, this object is achieved by a method, a sensor device, a motor vehicle and a computer program according to the independent patent claims. Advantageous further developments and further embodiments are the subject of the dependent claims.

The improved concept is based on the idea of transforming a point cloud of scanning points of the sensor system generated in a sensor coordinate system into a reference coordinate system and of determining an angular position of the sensor system based on the transformed point cloud.

According to a first independent aspect of the improved concept, a method for calibrating an active optical sensor system is specified. A point cloud of sampling points, in particular a three-dimensional point cloud of sampling points, is generated by means of the active optical sensor system, each sampling point of the point cloud containing three spatial coordinates with respect to a sensor coordinate system. The point cloud is transformed into a reference coordinate system by means of a computing unit, in particular on the basis of a predefined transformation rule. A reference angular position of a virtual reference sensor system is determined by means of the computing unit based on the transformed point cloud. An angular position of the sensor system is determined by means of the computing unit based on the reference angular position.

Here and in the following, an active optical sensor system can be defined as such in that it has a light source or transmission unit, in particular for emitting several light pulses. Furthermore, an active optical sensor system has at least one optical detector, for example a receiving unit, in particular for detecting light, for example light pulses, in particular reflected components of the light pulses. The active optical sensor system is set up in particular to generate and output one or more sensor signals based on the detected reflected components.

The calibration of the active optical sensor system can in particular be understood to mean the determination of the angular position of the sensor system or the preparatory steps required for this.

Here and below, the point cloud can be understood to mean a collection of points, in particular the scanning points, in three-dimensional space. In particular, the point cloud consists of a set of coordinate tuples, each coordinate tuple corresponding to one of the paragraph points.

In particular, the point cloud consists of coordinate tuples of the scanning points in the sensor coordinate system and the transformed point cloud consists of corresponding coordinate tuples of the scanning points in the reference coordinate system.

A three-dimensional point cloud can in particular be understood to mean a point cloud whose coordinate tuples are three-dimensional. In the context of the active optical sensor system, this means, for example, that each scanning point generated by means of the active optical sensor system contains the three spatial coordinates. In particular, a distance from the sensor system can be measured by means of the sensor system. The distance can be measured, for example, using a time-of-flight (ToF) measurement.

The spatial coordinates of the scanning points can be given, for example, in Cartesian coordinates, in spherical coordinates or in spatial polar coordinates. In particular, each scanning point can be given by two angles with respect to the sensor system and a distance from the sensor system.

For example, a predefined exit point of a light beam from the sensor system can serve as the coordinate origin.

The transformation based on the transformation rule can in particular be understood to mean a linear mapping, by means of which corresponding three spatial coordinates of the scanning point in the reference coordinate system are calculated from the three spatial coordinates of the scanning point in the sensor coordinate system. The transformation of the point cloud includes, in particular, the transformation of each of the sampling points of the point cloud using the same transformation rule. In particular, the transformation can be described by a rotation and / or a translation.

The transformation or the transformation rule is given or predefined. In particular, the transformation clearly results from a nominal reference orientation of the virtual reference sensor system and a nominal orientation of the sensor system. In particular, the transformation maps the nominal orientation to the nominal reference orientation.

This can be understood in particular in such a way that the sensor coordinate system corresponds to an actual, possibly faulty, orientation of the sensor system in space. The nominal orientation can generally deviate from this. Correspondingly, the transformation into the reference coordinate system also transforms the deviation of the sensor coordinate system from the nominal orientation. The reference coordinate system accordingly exhibits a virtual deviation from a nominal reference orientation. Using this virtual deviation, the actual deviation of the sensor system or the sensor coordinate system from the nominal orientation can thus also be determined indirectly.

The virtual reference sensor system can in particular be understood to mean a fictitious sensor system which is identical to the sensor system, but which is rotated and / or displaced with respect to it in accordance with the transformation rule. In particular, in a situation in which the sensor system generates the point cloud, the virtual reference sensor system would generate the same scanning points directly in the reference coordinate system, that is to say generate the transformed point cloud directly.

In other words, the transformed point cloud can be understood as a virtual point cloud that was generated by means of the virtual reference sensor system.

The reference angular position is given in particular by a deviation of the orientation of the reference sensor system from a nominal reference orientation, it being possible for the nominal reference orientation to be defined, for example, by a nominal reference coordinate system. Correspondingly, the angular position of the sensor system can be given as a deviation of an orientation of the sensor system from a nominal orientation of the sensor system, which is defined, for example, by a nominal sensor coordinate system.

To generate one of the scanning points, light is emitted into the surroundings of the sensor system, in particular by means of a transmission unit of the sensor system, and reflected portions of the light are received by a receiving unit of the sensor system. The spatial coordinates of the respective scanning point are determined based on the reflected components. The receiving unit can in particular contain a plurality of detectors, the spatial coordinates of the scanning point being determined as a function of which of the detectors the reflected components are detected or primarily detected.

The fact that the angular position of the sensor system is determined as a function of the reference angular position of the virtual reference sensor system and the reference angular position in turn based on the transformed point cloud, so to a certain extent in the reference coordinate system, the determination of the angular position is independent of a nominal alignment of the sensor system. This is particularly advantageous because in this way the deviation can always be determined in a predefined reference coordinate system, which makes it possible to use methods in which the use of a specific calibration template can be dispensed with. For example, excellent structures in the vicinity of the sensor system, which in particular have straight lines, can be used in the reference coordinate system to determine the reference angular position. In the sensor coordinate system, these straight lines or marked structures may not be suitable for directly determining the angular position.

As a result, the improved concept allows the sensor system to be calibrated independently of its nominal orientation and without the use of a special calibration target or a special calibration template.

According to at least one embodiment of the method according to the improved concept, each sampling point of the point cloud is subjected to a linear transformation by means of the computing unit, which includes a rotation in order to transform the point cloud into the reference coordinate system.

According to at least one embodiment, the rotation is carried out by means of the computing unit as a rotation around one or more coordinate axes of a nominal sensor coordinate system. The nominal sensor coordinate system results in particular clearly from the nominal reference coordinate system through the inverse transformation rule. The transformation therefore maps the nominal sensor coordinate system to the nominal reference coordinate system.

It should be pointed out at this point that translations between the sensor coordinate system and the reference coordinate system or the corresponding nominal coordinate systems or the sensor system and the virtual reference sensor system are neglected here and below. In particular, the calibration of the sensor system can be understood as determining the angular position.

According to at least one embodiment, to generate the point cloud, light is transmitted into the surroundings of the sensor system by means of the transmission unit of the sensor system and the reflected portions of the light are received by the reception unit of the sensor system. Depending on the received reflected components, at least two first sampling points are determined by means of a first detector of the receiving unit and at least two second sampling points are determined by means of a second detector of the receiving unit.

The point cloud contains in particular the first and the second sampling points.

Here and in the following, the term “light” can be understood to include electromagnetic waves in the visible range, in the infrared range and / or in the ultraviolet range. Accordingly, the term “optical” can be understood to refer to light according to this understanding.

The light can in particular be light pulses or light beams, in particular laser pulses or laser beams.

The laser pulses or laser beams can be, for example, laser pulses or beams in the infrared spectral range, in particular with a wavelength of 905 nm or approximately 905 nm or 1,200 nm or approximately 1,200 nm. This can mean in each case a wavelength range with a width and distribution which are typical for the particular laser system used. The wavelengths mentioned can, within the scope of customary tolerances, correspond, for example, to peak wavelengths of the corresponding laser spectrum.

The transmission unit can in particular contain a laser, for example a semiconductor laser diode.

The first and the second detector can, for example, each be configured with photodiodes, in particular avalanche photodiodes.

To generate the point cloud, for example, an object in the vicinity of the sensor system, which can serve as a reference calibration object, is scanned, for example a lane marking line, a lane boundary, a guardrail or other object with straight or approximately straight lines.

According to at least one embodiment, the at least two first sampling points and the at least two second sampling points for determining the reference angular position are transformed into the reference coordinate system by transforming the point cloud. The reference angular position is determined by the computing unit as a function of the transformed first sampling points and the transformed second sampling points.

The transformed first and second sampling points are in particular included in the transformed point cloud.

The arithmetic unit can, for example, use the first and second scanning points to recognize that a reference object suitable for calibration is located in the vicinity of the sensor system, for example the marking line and the guardrail. This can be determined, for example, in that the transformed first sampling points lie on a straight line or approximately on a straight line and / or in that the transformed second sampling points lie on a straight line or approximately on a straight line.

The reference object as such can be recognized in particular in the reference coordinate system, which is advantageous because the reference coordinate system is independent of the nominal orientation of the sensor system and corresponding algorithms for recognizing the reference object only need to be kept for the reference coordinate system, but not also for the sensor coordinate system .

In accordance with at least one embodiment, at least one of the transformed first sampling points is correlated with at least one of the transformed second sampling points by means of the computing unit. The at least two transformed sampling points are compared with a result of the correlation by means of the arithmetic unit and the reference angular position is determined by the arithmetic unit as a function of a result of the comparison.

The correlation can for example be understood in such a way that a curve of a predetermined type, for example a straight line, is laid through the sampling points to be correlated. To compare the at least two transformed first sampling points with the result of the correlation, wherein the above-mentioned curve or straight line can be referred to as the result of the correlation, for example, a further curve or straight line is laid through the at least two transformed first sampling points. The two curves are compared with one another in order to determine the reference angular position.

In the case of straight lines, the two straight lines generally enclose an angle. If the nominal reference angular position corresponds exactly to the actual reference angular position, the angle is equal to zero. If this is not the case, the angle or angles between the two straight lines, for example expressed in spherical coordinates, can be determined and corresponds to the reference angular position.

Corresponding points of the different detectors allow conclusions to be drawn about the actual alignment of the reference object. In contrast, the points of one of the detectors are aligned, for example, in accordance with an apparent direction of the reference object. The comparison of the two directions therefore gives the reference angular position.

According to at least one embodiment, the reference angular position is determined as a virtual deviation of an orientation of the virtual reference sensor system from a nominal reference orientation of the virtual reference sensor system.

According to at least one embodiment, the angular position is determined as a deviation of an orientation of the sensor system from a nominal orientation of the sensor system. A value of the deviation, or possibly values of the deviation, is equal to a value, or corresponding values are equal to the virtual deviation.

The value or the values of the deviation or the virtual deviation are in particular one or more angles of rotation. The angles of rotation in particular convert the nominal reference coordinate system into the reference coordinate system or vice versa, or the sensor coordinate system into the nominal sensor coordinate system or vice versa.

According to at least one embodiment, the deviation is determined as the pitch angle, yaw angle and / or roll angle of the sensor system with respect to the nominal orientation of the sensor system.

The same applies in particular to the reference deviation, which is determined, for example, as the pitch angle, yaw angle and / or roll angle of the virtual reference sensor system with respect to the nominal reference orientation of the reference sensor system.

In particular, the nominal sensor coordinate system can be converted into the sensor coordinate system by a maximum of three rotations about respective coordinate axes of the nominal sensor coordinate system.

According to at least one embodiment, the transformation is carried out on the basis of the predetermined transformation rule, the predetermined transformation rule being defined by a geometric relationship between the nominal orientation of the sensor system and the nominal reference orientation of the virtual reference sensor system.

According to at least one embodiment, the nominal reference orientation is through a longitudinal axis, a transverse axis and a normal axis Defined motor vehicle on which the sensor system is mounted.

The longitudinal axis of the motor vehicle can, for example, correspond to a direction of travel, in particular a forward direction of travel, of the motor vehicle or be parallel to this when a steering angle or a wheel angle of the motor vehicle is equal to zero or in a neutral position. The transverse axis of the motor vehicle is, for example, perpendicular to the longitudinal axis, so that the longitudinal axis spans a plane with the transverse axis that is aligned parallel to a surface on which the motor vehicle is located. The normal axis is perpendicular to the longitudinal and transverse axes.

According to a further independent aspect of the improved concept, a sensor device for a motor vehicle is specified which has an active optical sensor system and a computing unit coupled to the sensor system. The sensor system is set up to generate a point cloud, in particular a three-dimensional point cloud, of sampling points, with each sampling point of the point cloud containing three spatial coordinates with respect to a sensor coordinate system. The computing unit is set up to transform the point cloud into a reference coordinate system, to determine a reference angular position of a virtual reference sensor system based on the transformed point cloud and to determine an angular position of the sensor system based on the reference angular position.

In this case, the computing unit can be set up, for example, to control the sensor system for generating the scanning points.

According to at least one embodiment of the sensor device, the active optical sensor system is designed as a lidar system.

The lidar system includes, in particular, a transmission unit that includes, for example, a laser, in particular an infrared laser.

The lidar system also has at least two detectors, in particular detectors of a receiving unit of the lidar system, the detectors in particular being designed as avalanche photodiodes.

In embodiments in which the receiving unit contains three or more detectors which are each designed as avalanche photodiodes, the detectors are arranged, for example, linearly or as a matrix in rows and columns.

Further embodiments of the sensor device according to the improved concept result directly from the various embodiments of the method according to the improved concept and vice versa. In particular, a sensor device, for example the computing unit of the sensor device, is set up or programmed according to the improved concept to carry out a method according to the improved concept or carries out such a method.

According to a further independent aspect of the improved concept, a motor vehicle with a sensor device according to the improved concept is specified.

According to a further independent aspect of the improved concept, a computer program with instructions is specified. When the computer program is executed by a sensor device according to the improved concept, in particular by a computing unit of the sensor device, the commands cause the sensor device, in particular the computing unit, to carry out a method according to the improved concept.

According to a further independent aspect of the improved concept, a computer-readable storage medium is specified on which a computer program according to the improved concept is stored.

Further features of the invention emerge from the claims, the figures and the description of the figures. The features and combinations of features mentioned above in the description as well as the features and combinations of features mentioned below in the description of the figures and / or shown alone in the figures can be used not only in the specified combination, but also in other combinations without departing from the scope of the invention . Embodiments of the invention that are not explicitly shown and explained in the figures, but emerge and can be generated from the explained embodiments by means of separate combinations of features, are thus also to be regarded as being covered and disclosed. Designs and combinations of features are also to be regarded as disclosed, which therefore do not have all the features of an originally formulated independent claim. In addition, designs and combinations of features, in particular through the statements set out above, are to be regarded as disclosed that go beyond the combinations of features set forth in the back-references of the claims or differ from them.

• 1 ein Kraftfahrzeug mit einer beispielhaften Ausführungsform einer Sensorvorrichtung nach dem verbesserten Konzept;
• 2 ein Kraftfahrzeug mit einer weiteren beispielhaften Ausführungsform einer Sensorvorrichtung nach dem verbesserten Konzept;
• 3 eine Sendeeinheit eines aktiven optischen Sensorsystems einer weiteren beispielhaften Ausführungsform einer Sensorvorrichtung nach dem verbesserten Konzept;
• 4 eine Empfangseinheit eines aktiven optischen Sensorsystems einer weiteren beispielhaften Ausführungsform einer Sensorvorrichtung nach dem verbesserten Konzept;
• 5 eine schematische Darstellung einer Punktwolke gemäß einer beispielhaften Ausführungsform eines Verfahrens nach dem verbesserten Konzept;
• 6 eine schematische Darstellung einer transformierten Punktwolke gemäß einer weiteren beispielhaften Ausführungsform eines Verfahrens nach dem verbesserten Konzept;
• 7 ein Sensorkoordinatensystem und ein nominales Sensorkoordinatensystem; und
• 8 ein Referenzkoordinatensystem und ein nominales Referenzkoordinatensystem.

In the figures show:

• 1 a motor vehicle with an exemplary embodiment of a sensor device according to the improved concept;
• 2 a motor vehicle with a further exemplary embodiment of a sensor device according to the improved concept;
• 3 a transmitting unit of an active optical sensor system of a further exemplary embodiment of a sensor device according to the improved concept;
• 4th a receiving unit of an active optical sensor system of a further exemplary embodiment of a sensor device according to the improved concept;
• 5 a schematic representation of a point cloud according to an exemplary embodiment of a method according to the improved concept;
• 6th a schematic representation of a transformed point cloud according to a further exemplary embodiment of a method according to the improved concept;
• 7th a sensor coordinate system and a nominal sensor coordinate system; and
• 8th a reference coordinate system and a nominal reference coordinate system.

In 1 is a motor vehicle 1 shown which a sensor device 7th according to the improved concept.

The sensor device 7th exhibits a lidar system 2 on, with a nominal orientation defined by a longitudinal axis 17th of the motor vehicle 1 , a transverse axis 18th of the motor vehicle 1 and a normal axis, not shown, of the motor vehicle 1 .

In particular, the lidar system 2 Emit laser pulses with an emission angle, with the corresponding laser beams 13 lie within a plane at different deflection angles. If the emission angle is zero, the emission direction of the laser beam corresponds 13 for example the longitudinal axis 17th , provided the actual orientation of the sensor system 2 is exactly the same as the nominal orientation. The laser beams 13 for different emission angles lie in this case in the through the longitudinal axis 17th and the transverse axis 18th spanned plane.

The sensor device 7th also has a computing unit 4th on that with the lidar system 2 connected is.

In 2 is the motor vehicle 1 also shown. The sensor device 7th corresponds largely to the sensor device 7th out 1 , the sensor device 7th in 2 a lidar system 3 whose nominal orientation differs from the nominal orientation of the lidar system 2 out 1 differs. For example, the nominal orientation of the lidar system 3 90 ° from the nominal orientation of the lidar system 2 be rotated around the normal axis of the motor vehicle.

This nominal orientation is used below as a non-limiting example. The corresponding steps and procedures described can be used for other nominal orientations of the lidar system 3 understand accordingly.

3 shows schematically a transmission unit 8th of the lidar system 3 , which includes in particular an infrared laser, as well as from the transmitter unit 8th emitted laser beams 13 . In addition, in 3 schematically an object 19th in the vicinity of the lidar system 3 shown. The upper figure in 3 corresponds, for example, to a viewing direction parallel to the longitudinal axis 17th on the lidar system 3 and the lower figure in 3 corresponds, for example, to a viewing direction parallel to the normal axis of the motor vehicle 1 .

As in the pictures of the 3 is recognizable, a respective beam expansion of the laser beams 13 turn out differently at different levels.

In 4th are schematically a receiving unit 9 , a lens device 21st as well as a mirror 20th of the lidar system 3 shown.

The receiving unit 9 contains, for example, several, in the example shown the 4th three, avalanche photodiodes 10 , 11 , 12 which can be arranged linearly next to one another, for example. The mirror 20th is for example rotatable about an axis of rotation 22nd of the mirror 20th stored.

The view in 4th can, for example, as a top view, that is, as a view parallel to the normal axis of the motor vehicle 1 in 2 , on the lidar system 3 to be viewed as. The detectors 10 , 11 , 12 the receiving unit 9 are shown in a distorted perspective for the purpose of clarification. In an actual plan view, the detectors would 10 , 11 , 12 for example cover each other.

The transmitter unit 8th can for example with regard to the mirror 20th be arranged in such a way that upon rotation of the mirror 20th around the axis of rotation 22nd the emission angle of the light beam 13 can be varied.

A reception path for reflected components can also be used 14th of the rays of light 13 which for example from the object 19th were reflected through the mirror and lens assembly 21st to the receiving unit 9 to lead.

By rotating the mirror 20th around the axis of rotation 22nd can any of the detectors 10 , 11 , 12 reflected components incident from different directions 14th detect. The current position of the mirror 20th can for example be determined via a rotary encoder (not shown) coupled to a shaft (not shown) aligned along the axis of rotation.

By the current position of the mirror 20th For example, it is known at any point in time, can be based on the time sequence of the detected light beams for each of the detectors 10 , 11 , 12 a set of sample points can be generated. The amount of sample points required for different angular positions of the mirror 20th or rotation positions or times of the mirror 20th by means of one of the detectors 10 , 11 , 12 can also be referred to as the individual position or layer of the sampling points.

The entirety of all based on the detectors 10 , 11 , 12 Sampling points generated in this way are provided by means of the lidar system 3 generated point cloud.

The point cloud is designed in particular as a three-dimensional point cloud, since in addition to the corresponding angular positions and the information about which detector is being used 10 , 11 , 12 the sampling point decreases, so does the distance of the object 19th can be determined via a time of flight measurement.

In 5 is one made in this way by means of the lidar system 3 generated point cloud 6th shown. In 5 For example, different positions of the scanning points are shown as different line types. The sampling points of the point cloud 6th for example correspond to a guardrail that is roughly parallel to the longitudinal axis 17th of the motor vehicle 1 is aligned.

In particular, the sampling points of the point cloud lie 6th as three-dimensional coordinate tuples in a sensor coordinate system xs', ys', a zs' axis perpendicular to the axes xs' and ys' not being shown.

The following is a mode of operation of the sensor device 7th using an exemplary embodiment of a method according to the improved concept with reference in particular to FIG 5 to 8th described.

First is the point cloud 6th , as described above, by means of the lidar system 3 generated. The point cloud 6th is then by means of the computing unit 4th transformed into a reference coordinate system x0 ', y0'.

A corresponding transformation rule is predefined for this. The transformation rule is defined in particular in such a way that it has a nominal orientation of the lidar system 3 transformed to a nominal reference orientation. The nominal reference orientation can be the orientation of the lidar system, for example 2 out 1 correspond. Accordingly, the lidar system 2 , instead of a physical existing sensor system, for example as a virtual reference sensor system 2 be understood.

In the example described, the nominal orientations of the lidar system differ 3 and the reference sensor system 2 for example by rotating it by 90 degrees around the normal axis of the motor vehicle 1 .

The transformation of the point cloud 6th into the transformed point cloud 6 ' such as in 6th is shown, that is to say in the reference coordinate system x0 ', y0', takes place accordingly by a rotation through 90 ° about the normal axis of the motor vehicle 1 by using a corresponding rotation mapping.

As the actual orientation of the lidar system 3 but not necessarily exactly the nominal orientation of the lidar system 3 any existing deviation is also transformed.

The situation is in 7th and 8th shown in more detail.

In 7th the sensor coordinate system xs ', ys' is shown. In addition, there are first sampling points 15a , 15b , 15c and second sampling points 16a , 16b , 16c the point cloud 6th shown. The first sampling points 15a , 15b , 15c lie approximately on a straight line, which is due to the fact that the reference object in the example of a guardrail, as in 5 can be seen, has approximately straight lines. The second sampling points are also correspondingly 16a , 16b , 16c on a straight line. This was the first sampling point 15a , 15b , 15c for example with a first detector 10 the receiving unit 9 generated and the second sample points 16a , 16b , 16c with a second detector 11 the receiving unit. The first sampling points 15a , 15b , 15c thus belong, for example, to a first layer of sampling points, the second sampling points 16a , 16b , 16c to a second layer of sampling points.

In 7th a nominal sensor coordinate system xs, ys is also shown. The sensor coordinate system xs ', ys' differs from the nominal sensor coordinate system xs, ys, for example by a rotation by an angle δs about the z-axis, not shown, of the two sensor coordinate systems xs ', ys' or xs, ys.

In 8th the result of the transformation is shown. In particular, the reference coordinate system x0 ', y0' is shown, which is generated by rotating the sensor coordinate system xs ', ys' through 90 ° about the normal axis of the motor vehicle 1 was generated.

A nominal reference coordinate system x0, y0 is also shown. The nominal coordinate systems x0, y0 or xs, ys merge into one another through the predefined transformation.

Correspondingly, there is also the same deviation δ0 = δs between the reference coordinate system x0 ', y0' and the nominal reference coordinate system x0, y0 as between the sensor coordinate system xs ', ys' and the nominal sensor coordinate system xs, ys.

From the point of view of the virtual reference sensor system 2 , i.e. when looking forward along the x0 axis of the nominal reference coordinate system, the appearance of the point cloud differs 6 ' on the appearance of the point cloud 6th from the direction of view of the lidar system 3 , that is, along the xs axis of the nominal sensor coordinate system xs, ys.

The sample points of the transformed point cloud 6 ' can from the computing unit 4th be analyzed for example in such a way that it is recognized that the sampling points 15a , 15b , 15c are on the corresponding straight line as well as the sampling points 16a , 16b , 16c on the further corresponding straight line. Corresponding and using different detectors 10 , 11 generated sampling points 15a , 16a can by means of the computing unit 4th can be correlated with each other by drawing a straight line through these two points. Because the two points 15a , 16a correspond to one another, corresponds to a deviation of this straight line from that through the sampling points 15a , 15b , 15c defined straight lines also of the deviation δ0 between the reference coordinate systems x0 ', y0' and x0, y0.

The deviation of the sensor coordinate system xs ', ys' from the nominal sensor coordinate system xs, ys can thus be determined as δ0 = δs.

According to the improved concept, the angular position of the sensor system is determined via an apparent detour, in that the point cloud is first transformed into a reference coordinate system and the corresponding reference angular position is determined based on the transformed point cloud. What is achieved thereby, however, is that online calibration of the sensor system for any orientations, in particular nominal orientations, of the sensor system becomes possible, since online calibration for the reference coordinate system is possible in the manner described.

Claims (15)

Method for calibrating an active optical sensor system (3), whereby a point cloud (6) of sampling points is generated by means of the active optical sensor system (3), each sampling point of the point cloud (6) having three spatial coordinates with respect to a sensor coordinate system (xs ', ys') includes; characterized in that - the point cloud (6) is transformed into a reference coordinate system (x0 ', y0') by means of a computing unit (4); - A reference angular position (δ0) of a virtual reference sensor system is determined by means of the computing unit (4) based on the transformed point cloud (6 '); and - an angular position (δs) of the sensor system (3) is determined by means of the computing unit (4) based on the reference angular position (δ0). Procedure according to Claim 1 , characterized in that each sampling point is subjected to a linear transformation by means of the arithmetic unit (4) which includes a rotation in order to transform the point cloud (6) into the reference coordinate system (x0 ', y0'). Procedure according to Claim 2 , characterized in that the rotation is carried out by means of the computing unit (4) as a rotation around one or more coordinate axes of a nominal sensor coordinate system (xs, ys). Method according to one of the Claims 1 to 3 , characterized in that to generate the point cloud (6) - by means of a transmitter unit (8) of the sensor system (3) light (13) is transmitted into the surroundings of the sensor system (3) and reflected portions (14) of the light (13) through a receiving unit (9) of the sensor system (3) are received; and - depending on the received reflected components (14) at least two first sampling points (15a, 15b, 15c) are determined by means of a first detector (10) of the receiving unit (9) and at least two second sampling points (16a, 16b, 16c) by means of a second detector (11) of the receiving unit (9) can be determined. Procedure according to Claim 4 , characterized in that for determining the reference angular position (δ0) - the at least two first sampling points (15a, 15b, 15c) and the at least two second sampling points (16a, 16b, 16c) by transforming the point cloud (6) into the reference coordinate system ( x0 ', y0') are transformed; - The reference angular position (δ0) is determined by means of the arithmetic unit (4) depending on the transformed first sampling points (15a, 15b, 15c) and the transformed second sampling points (16a, 16b, 16c). Procedure according to Claim 5 , characterized in that - at least one of the transformed first sampling points (15a) is correlated with at least one of the transformed second sampling points (16b) by means of the computing unit (4); - The at least two transformed first sampling points (15a, 15b, 15c) are compared with a result of the correlation by means of the computing unit (4); and - the reference angular position (δ0) is determined by means of the computing unit (4) as a function of a result of the comparison. Method according to one of the Claims 1 to 6th , characterized in that the reference angular position (δ0) is determined as a virtual deviation (δ0) of an orientation of the virtual reference sensor system from a nominal reference orientation of the virtual reference sensor system. Procedure according to Claim 7 , characterized in that - the angular position (δs) is determined as a deviation (δs) of an orientation of the sensor system (3) from a nominal orientation of the sensor system (3); - a value deviation (δs) is equal to a value of the virtual deviation (δ0) or several values of the deviation (δs) are equal to several corresponding values of the virtual deviation (δ0). Procedure according to Claim 8 , characterized in that the deviation (δs) is determined as the pitch angle, yaw angle (δs) and / or roll angle of the sensor system (3) with respect to the nominal orientation of the sensor system (3). Method according to one of the Claims 8 or 9 , characterized in that the transformation is carried out on the basis of a predetermined transformation rule which is defined by a geometric relationship between the nominal orientation of the sensor system (3) and the nominal reference orientation of the virtual reference sensor system. Method according to one of the Claims 7 to 9 , characterized in that the nominal reference orientation is defined by a longitudinal axis (17), a transverse axis (18) and a normal axis of a motor vehicle (1) on which the sensor system (3) is mounted. Sensor device for a motor vehicle (1), the sensor device (7) having an active optical sensor system (3) and a computing unit (4) coupled to the sensor system (3); - The sensor system (3) being set up to generate a point cloud (6) of sampling points, each sampling point of the point cloud (6) containing three spatial coordinates with respect to a sensor coordinate system (xs ', ys'); characterized in that the processing unit (4) is set up to - transform the point cloud (6) into a reference coordinate system (x0 ', y0'); - to determine a reference angular position (δ0) of a virtual reference sensor system based on the transformed point cloud (6 '); and - to determine an angular position (δs) of the sensor system (3) based on the reference angular position (δ0). Sensor device according to Claim 12 , characterized in that the active optical sensor system (3) is designed as a lidar system. Motor vehicle with a sensor device (7) according to one of the Claims 12 or 13 . Computer program with commands which, when the computer program is executed by a sensor device (7), according to one of the Claims 12 or 13 , the sensor device (7) to cause a method according to one of the Claims 1 to 11 perform.

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