Method of determining an alignment error of an antenna and vehicle with an antenna and a detection device

We claim: 1. A method of determining an alignment error of an antenna, wherein: the antenna is installed on a vehicle and in cooperation with a radar system, the radar system is configured to determine a plurality of detections by: emitting a first portion of electromagnetic radiation through the antenna; receiving a second portion of electromagnetic radiation through the antenna; and evaluating the second portion of electromagnetic radiation in dependence of the first portion of electromagnetic radiation in order to localize areas of reflection of the first portion of electromagnetic radiation in a vicinity of the antenna; and determining the alignment error of the antenna by: determining a first detection and at least a second detection of the plurality of detections by using the radar system, and determining the alignment error by performing a joint evaluation of the first detection and the second detection by at least: evaluating a first algebraic expression (A′, A″) or a second algebraic expression (B′, B″), wherein: the first algebraic expression (A′, A″) is dependent from an angular velocity component (ω yaw ) of the vehicle; the first algebraic expression (A′, A″) is not dependent from a linear velocity component (v x host ) representing the velocity of the vehicle in a heading direction of the vehicle; the second algebraic expression (B′, B″) is dependent from a linear velocity component (v x host ) representing the velocity of the vehicle in the heading direction of the vehicle; the second algebraic expression (B′, B″) is not dependent from an angular velocity component (ω yaw ) of the vehicle; and selecting, based on the velocity of the vehicle, one of the first algebraic expression (A′, A″) or the second algebraic expression (B′, B″) for the joint evaluation. 2. The method of claim 1 , said method further comprising processing at least one of the first detection and the at least second detection from the radar system in dependence of the alignment error. 3. The method of claim 1 , wherein each of the first detection and the second detection comprises an angular position relative to a reference angular position of the antenna. 4. The method of claim 1 , wherein each of the first detection and the second detection comprises a velocity of the antenna relative to a velocity of an area of reflection being associated with the first detection and the second detection. 5. The method of claim 1 , wherein each of the first detection and the second detection comprises an angular position relative to a reference angular position of the antenna, and each of the first detection and the second detection comprises a velocity of the antenna relative to a velocity of an area of reflection being associated with the first detection and the second detection. 6. The method of claim 1 , wherein, from a plurality of detections from the radar system, the joint evaluation is only based on the first detection or the second detection. 7. The method of claim 1 , wherein the joint evaluation further comprises one of: evaluating the first algebraic expression (A′, A″) under a condition that the velocity of the vehicle in a heading direction of the vehicle is above a first threshold; or evaluating the first algebraic expression (A′, A″) under a condition that the velocity of the vehicle in a direction being transverse to the heading direction is below a second threshold. 8. The method of claim 7 , wherein the first algebraic expression (A′, A″) and the second algebraic expression (B′, B″) do not include a logarithm. 9. The method of claim 1 , wherein the joint evaluation further comprises: evaluating the first algebraic expression (A′, A″) under a condition that the velocity of the vehicle in a heading direction of the vehicle is above a first threshold; and evaluating the first algebraic expression (A′, A″) under a condition that the velocity of the vehicle in a direction being transverse to the heading direction is below a second threshold. 10. The method of one of claim 1 , wherein the joint evaluation further comprises one of: evaluating the second algebraic expression (B′, B″) under a condition that the velocity of the vehicle in a heading direction of the vehicle is below a third threshold; or evaluating the second algebraic expression (B′, B″) under a condition that the velocity of the vehicle in a direction being transverse to the heading direction is above a fourth threshold. 11. The method of one of claim 1 , wherein the joint evaluation further comprises: evaluating the second algebraic expression (B′, B″) under a condition that the velocity of the vehicle in a heading direction of the vehicle is below a third threshold; and evaluating the second algebraic expression (B′, B″) under a condition that the velocity of the vehicle in a direction being transverse to the heading direction is above a fourth threshold. 12. The method of claim 1 , wherein the method comprises: determining a plurality of candidates for the alignment error, wherein the alignment error is determined from the candidates by processing the candidates by using at least one of a random sample consensus algorithm or a Kalman filter. 13. The method of claim 1 , wherein: the first detection is associated with a first object; the second detection is associated with a second object; and the first object is stationary. 14. The method of claim 1 , wherein: the first detection is associated with a first object; the second detection is associated with a second object; the first object and the second object are stationary; and the vehicle is not stationary. 15. A radar system including, a control unit configured to: determine a plurality of detections on the basis of a first portion of electromagnetic radiation emitted through an antenna installed at a vehicle, and a second portion of electromagnetic radiation received through the antenna; and determine an alignment error of the antenna by: determining a first detection and at least a second detection of the plurality of detections; and determining the alignment error by performing of a joint evaluation of the first detection and the second detection including evaluating a first algebraic expression (A′, A″) or a second algebraic expression (B′, B″), wherein: the first algebraic expression (A′, A″) is dependent from an angular velocity component (ω yaw ) of the vehicle; the first algebraic expression (A′, A″) is not dependent from a linear velocity component (v x host ) representing the velocity of the vehicle in a heading direction of the vehicle; the second algebraic expression (B′, B″) is dependent from a linear velocity component (v x host ) representing the velocity of the vehicle in the heading direction of the vehicle; and the second algebraic expression (B′, B″) is not dependent from an angular velocity component (ω yaw ) of the vehicle; and selecting, based on the velocity of the vehicle, one of the first algebraic expression (A′, A″) or the second algebraic expression (B′, B″) for performing the joint evaluation. 16. The radar system claim 15 , wherein the control unit is configured to perform the joint evaluation by at least one of: evaluating the first algebraic expression (A′, A″) under a condition that the velocity of the vehicle in a heading direction of the vehicle is above a first threshold; evaluating the first algebraic expression (A′, A″) under a condition that the velocity of the vehicle in a direction being transverse to the heading direction is below a second threshold; evaluating the second algebraic expre