RoboTron-Sim: Improving Real-World Driving via Simulated Hard-Case

Baihui Xiao; Chengjian Feng; Zhijian Huang; Feng Yan; Yujie Zhong; Lin Ma

2025 ICCV ICCV 2025

RoboTron-Sim: Improving Real-World Driving via Simulated Hard-Case

Abstract

Collecting real-world data for rare high-risk scenarios, long-tailed driving events, and complex interactions remains challenging, leading to poor performance of existing autonomous driving systems in these critical situations. In this paper, we propose RoboTron-Sim that improves real-world driving in critical situations by utilizing simulated hard cases. First, we develop a simulated dataset called Hard-case Augmented Synthetic Scenarios (HASS), which covers 13 high-risk edge-case categories, as well as balanced environmental conditions such as day/night and sunny/rainy. Second, we introduce Scenario-aware Prompt Engineering (SPE) and an Image-to-Ego Encoder (I2E Encoder) to enable multimodal large language models to effectively learn real-world challenging driving skills from HASS, via adapting to environmental deviations and hardware differences between real-world and simulated scenarios. Extensive experiments on nuScenes show that RoboTron-Sim improves driving performance in challenging scenarios by 50%, achieving state-of-the-art results in real-world open-loop planning. Qualitative results further demonstrate the effectiveness of RoboTron-Sim in better managing rare high-risk driving scenarios.

🌉 Interdisciplinary Bridge — Artificial Intelligence and Computer Vision and Machine Learning and Robotics

🧭 Keyword Pioneer — edge case

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy, Speech & Audio

Authors

Baihui Xiao , Chengjian Feng , Zhijian Huang , Feng Yan , Yujie Zhong , Lin Ma

Topics

Artificial Intelligence > Core AI > Autonomous Vehicles Artificial Intelligence > Core AI > Multimodal Learning Machine Learning > Application Areas > Domain Adaptation Computer Vision > Domain-Specific > Autonomous Driving Robotics > Capabilities > Motion Planning

Keywords

motion planning domain adaptation autonomous driving multi-modal learning multimodal large language model scenario simulation scenario generation large language model edge case

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