TL;DR
AADS introduces a novel simulation method that combines real-world imagery with simulated traffic to produce highly realistic, scalable, and annotated data for autonomous driving system training and validation.
Contribution
The paper presents a data-driven augmentation approach that enhances simulation realism and scalability by integrating real-world images with simulated traffic flows.
Findings
Generated photo-realistic, annotated images suitable for training.
Validated effectiveness across detection, segmentation, and prediction tasks.
Outperforms traditional simulation methods in realism and scalability.
Abstract
Simulation systems have become an essential component in the development and validation of autonomous driving technologies. The prevailing state-of-the-art approach for simulation is to use game engines or high-fidelity computer graphics (CG) models to create driving scenarios. However, creating CG models and vehicle movements (e.g., the assets for simulation) remains a manual task that can be costly and time-consuming. In addition, the fidelity of CG images still lacks the richness and authenticity of real-world images and using these images for training leads to degraded performance. In this paper we present a novel approach to address these issues: Augmented Autonomous Driving Simulation (AADS). Our formulation augments real-world pictures with a simulated traffic flow to create photo-realistic simulation images and renderings. More specifically, we use LiDAR and cameras to scan…
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