Obstacle detection is crucial to the operation of autonomous driving systems, which rely on multiple sensors, such as cameras and LiDARs, combined with code logic and deep learning models to detect obstacles for time-sensitive decisions. Consequently, obstacle detection latency is critical to the safety and effectiveness of autonomous driving systems. However, the latency of the obstacle detection module and its resilience to various changes in the LiDAR point cloud data are not yet fully understood. In this work, we present the first comprehensive investigation on measuring and modeling the performance of the obstacle detection modules in two industry-grade autonomous driving systems, i.e., Apollo and Autoware. Learning from this investigation, we introduce ADPerf, a tool that aims to generate realistic point cloud data test cases that can expose increased detection latency. Increasing latency decreases the availability of the detected obstacles and stresses the capabilities of subsequent modules in autonomous driving systems, i.e., the modules may be negatively impacted by the increased latency in obstacle detection. We applied ADPerf to stress-test the performance of widely used 3D obstacle detection modules in autonomous driving systems, as well as the propagation of such tests on trajectory prediction modules. Our evaluation highlights the need to conduct performance testing of obstacle detection components, especially 3D obstacle detection, as they can be a major bottleneck to increased latency of the autonomous driving system. Such an adverse outcome will also further propagate to other modules, reducing the overall reliability of autonomous driving systems.

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