VRF: Vehicle Road-side Point Cloud Fusion
Kaleem Nawaz Khan, A.J. Khalid, Yash Turkar, Karthik Dantu, Fawad Ahmad
Abstract
Autonomous vehicles and human drivers are prone to line-of-sight limitations. Road-side mounted 3D sensors like LiDARs can augment a vehicle's on-board perception. However, this entails fusing 3D frames at low latency and high accuracy. Road-side and vehicle 3D frames are captured from different viewpoints. This adversely affects alignment accuracy and can be computationally expensive. To this end, VRF optimizes for both latency and accuracy by decoupling the alignment process into indirect and direct alignments. First, VRF indirectly aligns the 3D frames by aligning them to a common reference point i.e., a vehicle's on-board 3D map. Then, it directly aligns the two point clouds to refine this alignment. To ensure high accuracy, it incorporates novel offline registration and alignment accuracy forecasting modules. To ensure low latency, it uses a fast fusion pipeline that caches previous and offline computations. To our knowledge, VRF is the first vehicle road-side cooperative system to ensure cm-level accuracy and end-to-end latency less than 20 ms. Most importantly, its latency is below the 100 ms threshold required for autonomous vehicles to react to external events. Finally, VRF can improve reaction time to external events by as much as 5 seconds1.