Complex-valued Convolutional Neural Networks for Enhanced Radar Signal Denoising and Interference Mitigation

Autonomous driving highly depends on capable sensors to perceive the environment and to deliver reliable information to the vehicles' control systems. To increase its robustness, a diversified set of sensors is used, including radar sensors. Radar is a vital contribution of sensory information, providing high resolution range as well as velocity measurements. The increased use of radar sensors in road traffic introduces new challenges. As the so far unregulated frequency band becomes increasingly crowded, radar sensors suffer from mutual interference between multiple radar sensors. This interference must be mitigated in order to ensure a high and consistent detection sensitivity. In this paper, we propose the use of Complex-Valued Convolutional Neural Networks (CVCNNs) to address the issue of mutual interference between radar sensors. We extend previously developed methods to the complex domain in order to process radar data according to its physical characteristics. This not only increases data efficiency, but also improves the conservation of phase information during filtering, which is crucial for further processing, such as angle estimation. Our experiments show, that the use of CVCNNs increases data efficiency, speeds up network training and substantially improves the conservation of phase information during interference removal.

Automated summary

Autonomous driving relies heavily on sensors to perceive the environment and deliver information to control systems. Radar sensors play a vital role in providing high resolution range and velocity measurements. However, the increased use of radar sensors in road traffic leads to mutual interference, which can be mitigated using Complex-Valued Convolutional Neural Networks (CVCNNs) to improve data efficiency and phase information conservation.