The Radar Ghost Dataset -- An Evaluation of Ghost Objects in Automotive Radar Data
This work addresses a specific issue in autonomous vehicle perception for researchers, but it is incremental as it focuses on dataset creation and preliminary evaluation.
The authors tackled the problem of ghost objects in automotive radar data, which cause false positives in perception systems, by presenting a manually annotated dataset and evaluating two identification approaches, though no concrete performance numbers are provided.
Radar sensors have a long tradition in advanced driver assistance systems (ADAS) and also play a major role in current concepts for autonomous vehicles. Their importance is reasoned by their high robustness against meteorological effects, such as rain, snow, or fog, and the radar's ability to measure relative radial velocity differences via the Doppler effect. The cause for these advantages, namely the large wavelength, is also one of the drawbacks of radar sensors. Compared to camera or lidar sensor, a lot more surfaces in a typical traffic scenario appear flat relative to the radar's emitted signal. This results in multi-path reflections or so called ghost detections in the radar signal. Ghost objects pose a major source for potential false positive detections in a vehicle's perception pipeline. Therefore, it is important to be able to segregate multi-path reflections from direct ones. In this article, we present a dataset with detailed manual annotations for different kinds of ghost detections. Moreover, two different approaches for identifying these kinds of objects are evaluated. We hope that our dataset encourages more researchers to engage in the fields of multi-path object suppression or exploitation.