SENSOR SYSTEM FOR CAPTURING THE ENVIRONMENT OF AT LEAST A FIRST AND A SECOND VEHICLE UNIT PIVOTABLY COUPLED TO ONE ANOTHER

Abstract

A sensor system including at least a first and a second sensor unit. The sensor system is designed to at least partially capture the environment of at least a first and second vehicle unit pivotably coupled to one another. The first sensor unit is positionable on the first vehicle unit and the second sensor unit is positionable on the second vehicle unit. The first and second sensor unit capture different environmental areas. The sensor system has an electronic control unit connected to the first and second sensor unit and designed such that it jointly evaluates output data from the first and second sensor unit. The first and the second sensor unit each provide their sensor data with a synchronized item of time information. The electronic control unit is designed such that it takes into account relative positioning of the first and second sensor unit when generating an environmental model.

Claims

1. A sensor system comprising at least a first and a second sensor unit, wherein the sensor system is designed to at least partially capture the environment of at least a first and a second vehicle unit pivotably coupled to one another, wherein the first and the second sensor unit can be positioned separately from one another, wherein the first sensor unit is positionable on the first vehicle unit and the second sensor unit is positionable on the second vehicle unit, wherein the first and the second sensor unit capture different environmental areas, wherein the sensor system has an electronic control unit which is connected to the first and the second sensor unit and is designed such that it jointly evaluates the output data from the first and second sensor unit, wherein the first and the second sensor unit each provide their sensor data in a manner provided with an item of time information, synchronized by and/or relative to the electronic control unit, and the electronic control unit is designed such that it takes into account the relative positioning of the first and second sensor unit when generating an environmental model.

2. The sensor system as claimed in claim 1, wherein the first and the second sensor unit are positioned in a manner pivotable by a defined pivot angle relative to one another in terms of their relative positioning with respect to a first defined axis, and wherein the electronic control unit is designed such that the pivot angle and/or an item of information dependent thereon is/are taken into account when generating the environmental model at least at defined times, at synchronous times with respect to a common time base.

3. The sensor system as claimed in claim 1, wherein the environmental model is designed such that it has an at least two-dimensional map of positions and/or coordinates which has been/is stored and/or calculated in the electronic control unit and in which points and/or objects captured and/or detected by the first and the second sensor unit are provided as output data from the first and second sensor unit and are entered and/or included in the at least two-dimensional map, depending at least on the respective time information in the output data and the temporally substantially equal and/or synchronous pivot angle.

4. The sensor system as claimed in claim 1, wherein the at least two-dimensional map of the environmental model is in the form of a first table and/or matrix and/or database and, depicts a substantially two-dimensional map in which the sensor system is located and/or through which the sensor system is moved.

5. The sensor system as claimed in claim 1, wherein the output data from the first and second sensor unit each have at least the point in time and the distance and/or an item of position information and/or a speed and/or relative speed of detection of a point and/or an object by the corresponding sensor unit.

6. The sensor system as claimed in claim 1, wherein an item of information relating to the positioning in the sense of the static fastening of each sensor unit is available in the electronic control unit, wherein this information relating to the positioning is defined relative to a reference coordinate system of at least one of the vehicle units, the vehicle unit in which the sensor unit is positioned, stored and/or present, and at least one item of driving dynamics information relating to the first and/or the second vehicle unit is available, the speed in the longitudinal direction of the vehicle unit, and the pivot angle Θ between the first and second vehicle unit, and wherein, at least on the basis of this information, the electronic control unit calculates a sensor unit position for each sensor unit at defined times and calculates data of the environmental model on the basis of this sensor unit position and the output data from the sensor units.

7. The sensor system as claimed in claim 6, wherein the environmental model comprises static environmental data relating to points and/or objects captured by the sensor units, which are stored and/or calculated in an at least two-dimensional map of the environmental model as a first table and/or matrix and/or database, and dynamic environmental data, which are stored and/or calculated in an additional table and/or matrix and/or database and are generated on the basis of points and/or objects captured by the sensor units, wherein these points and/or objects have a speed themselves that differs from zero, or wherein the dynamic environmental data are stored and/or calculated in the first table and/or matrix and/or database, wherein the dynamic information is contained in the changes to the data records with different time stamps.

8. The sensor system as claimed in claim 1, wherein the at least two-dimensional map of the environmental model in the electronic control unit accesses further information and/or is supplemented with further information, from positions and/or coordinates for captured objects from a satellite navigation system and/or an externally generated at least two-dimensional map of the area traversed by the vehicle units.

9. The sensor system as claimed in claim 6, wherein the electronic control unit calculates a position of the first and/or second vehicle unit at least from the output data from the first and second sensor unit and the data from the at least two-dimensional map of the environmental model.

10. A method for generating or calculating an at least two-dimensional map of an environmental model as a first table and/or matrix and/or database by a sensor system as claimed in claim 1, wherein the electronic control unit calculates a position of the first and/or second vehicle unit at least from the output data from the first and second sensor unit and the data from the at least two-dimensional map of the environmental model.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0053] FIGS. 1 and 2 each show, in a schematic representation, exemplary aspects of the sensor system and the method.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0054] FIG. 1 shows, by way of example, a first and a second vehicle unit A, B, designed by way of example as a towing vehicle A and trailer B, which can be rotated or pivoted relative to one another by the pivot angle Θ1. The first vehicle unit A has the environmental sensors 1 to 5, which capture the environment, substantially to the front and to the side of the towing vehicle, and the second vehicle unit B has the environmental sensors 6 to 9. By way of example, the first sensor unit 1 and the second sensor unit 8 are positioned separately from one another on the two pivotably coupled vehicle units. An ECU (not shown) jointly evaluates the output data from the environmental sensors 1 to 9, wherein the output data each synchronously provide or have an item of time information for the respective output data. The respective capture area of each of the sensor units 1 to 9 is illustrated by way of example by the two beams each emanating from the sensor unit, wherein the capture area is in each case substantially laterally bounded by these two beams.

[0055] The mode of operation of the sensor system is illustrated by way of example on the basis of FIG. 2, wherein the function blocks 19, 20, 21 and 22 are embodied in the electronic control unit, also called the ECU. The ECU is provided with the output data or output signals from the sensor units 1 to 9, as well as vehicle dynamics signals or driving dynamics information 10, which in particular include the speed of the first and second vehicle unit themselves, as well as the pivot angle data Θ1 and an item of information relating to the variance of the pivot angle data Θ1, using the function block 11. In addition, the static positioning parameters of the sensor units or static installation parameters or the data relating to the relative positioning of the sensor units are available to the ECU in function block 12.

[0056] The ECU generates an environmental model, which can also be understood, for example, as a world perception, wherein static environmental data 20 and dynamic environmental data 21 are calculated as well as a map creation 22 of an at least two-dimensional map. From these data, the ECU calculates, for example, a vehicle position 30 based on the two-dimensional map and, for example, also based on global GPS coordinates, and provides an environmental model 31 based on the two-dimensional map. According to the example, this environmental model 31 is a fused static and dynamic environmental model.

[0057] The sensor unit position for each sensor unit, function block 19, or the corresponding information 19 is calculated from function blocks 10, 11 and 12, for example. In this case, {right arrow over (θ)}.sub.1:m,meas(t) is, for example, the vector of the articulation angle measurements and {right arrow over (σ)}.sub.θ1:m,meas(t) is, for example, the vector of the articulation angle measurement variances. {right arrow over (x)}.sub.1:m(t) denotes the estimated sensor state vectors in the reference coordinate system.

[0058] The driving dynamics information 10 relating to the first and/or the second vehicle unit A, B includes, for example, the speed in the longitudinal direction of the respective vehicle unit, as well as the pivot angle Θ between the first and second vehicle unit, wherein, on the basis of this information, the electronic control unit calculates a sensor unit position 19 for each sensor unit 1, 2, 3, 4, 5, 6, 7, 8, 9 at defined times and, on the basis of this sensor unit position 19 and the output data from the sensor units 1, 2, 3, 4, 5, 6, 7, 8, 9, calculates data relating to the static and the dynamic environmental model 20, 21 and thus the resulting environmental model 30.

[0059] According to the example, the dynamic environmental model and the two-dimensional map of the environmental model 22 are calculated at least on the basis of the driving dynamics information 10 and the sensor unit positions 19.

[0060] The driving dynamics information 10 is used to distinguish between dynamic and static captured objects/points which are included in the environmental data relating to the dynamic or static environmental model 20, 21.

[0061] In function blocks 20, 21, 22, the input data of the respective function block are respectively fused by way of example.

[0062] The environmental model of the static environmental data 20 includes, for example, points and/or objects which are captured by the sensor units 1 to 9 and are calculated and stored in the at least two-dimensional map of the environmental model 22 as a first table or matrix or database.

[0063] The dynamic environmental data 21, which are calculated and stored in an additional table or matrix or database, are generated, for example, on the basis of points and/or objects captured by the sensor units 1 to 9, wherein these points and/or objects themselves have a speed that differs from zero, or the dynamic environmental data 21 are calculated and stored in the first table or matrix or database, wherein the dynamic information is contained in the changes to the data records with different time stamps.

[0064] In the electronic control unit, the at least two-dimensional map 22 of the environmental model accesses further information, according to the example, or this map is supplemented with further information, from positions and/or coordinates for captured objects from a satellite navigation system and optionally, for example, from an externally generated at least two-dimensional map of the area traversed by the vehicle units A, B.