期刊
2023 CYBER-PHYSICAL SYSTEMS AND INTERNET-OF-THINGS WEEK, CPS-IOT WEEK WORKSHOPS
卷 -, 期 -, 页码 158-163出版社
ASSOC COMPUTING MACHINERY
DOI: 10.1145/3576914.3587711
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This paper discusses the software design patterns and vehicle interfaces used to transition vehicle controllers from simulation environments to open-road field experiments. The approach integrates model-based design, code generation, agile software development, and software and hardware-in-the-loop testing, with a focus on safety and dynamics of mixed autonomy in traffic. The paper emphasizes the importance of research interfaces, which provide strongly typed data streams accessible to non-software experts. The hardware platform interfaces and software design process for a mixed autonomy traffic experiment, as well as testing strategies, are described.
This paper describes the software design patterns and vehicle interfaces that were employed to transition vehicle controllers from simulation environments to open-road field experiments. The approach relies on a life cycle that utilizes model-based design and code generation, along with agile software development, and both softwareand hardware-in-the-loop testing, with additional safety margins. Autonomous designs should consider the dynamics of mixed autonomy in traffic to safely operate among humans. The software that provides a vehicle's behavior intelligence is often developed through simulation, which may have a mismatch between dynamics, or as a result of a reinforcement learning workflow, which may be a black box with challenges to analyze. In each of these cases, it is important to have research interfaces that provide strongly typed data streams accessible to researchers who are not software experts while continuing to satisfy safety and liveness constraints. This paper describes how we design the hardware platform interfaces and software design process for a mixed autonomy traffic experiment with a leader-follower scenario. Controller synthesis for these vehicles requires clearly articulated vehicle interfaces and software design patterns for successful onboard deployment. Testing strategies for such controllers are also described before algorithms are transitioned to full-scale field experiments with safety operators for the vehicles. Testing strategies include software-in-the-loop simulation testing, hardware-in-the-loop simulation, ghost-car testing, and read-only testing in live traffic. With our approach, we were not only able to validate our controller synthesized in scripts and simulation, but also able to scale deployment to multiple vehicles.
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