A Sequential Method for Automotive Millimeter-Wave Radar
Self-Calibration Based on Optimization 2023-01-7044
Implementation calibration of automotive radar systems plays a fundamental but
crucial role to guarantee sensor performance. The commonly used method relies on
the environment such as a specific test station for static calibration or a
straight metal guardrail for dynamic calibration. In this paper, a sequential
method for estimating the radar angle misalignment derived from the Lagrange
Multiplier Method in solving an optimization problem is proposed. The sequential
method, which requires radar measurements and vehicle speed measurements as
input, is more environment-free and can yield a consistent estimation. A
simulation study is conducted to validate the consistency and analyze the
influence of noise. The result shows that the radar azimuth measurement noise
has little influence that the bias could be compensated and the effect of
non-gaussianity is negligible. The radar velocity measurement noise bias and
vehicle speed measurement noise bias have a linear effect whose coefficient
depends on the radar orientation on the angle misalignment estimation. A real
road testing is carried out and the result demonstrates that the method proposed
could provide an estimation with an error no more than 0.26 degrees. An
artificial error with 1 degree is added to the calibration result of the
proposed method to study the miscalibration influence on sensor fusion based on
the neural net. The result shows that the precision and recall deteriorate
significantly with the artificial error, especially for the small targets like
pedestrians, the reduction could reach 14% for precision and 17% for recall.