Coping with intensively interactive scenarios is one of the significant challenges in the development of autonomous driving. Reinforcement learning (RL) offers an ideal solution for such scenarios through its self-evolution mechanism via interaction with the environment. However, the lack of sufficient safety mechanisms in common RL leads to the fact that agent often find it difficult to interact well in highly dynamic environment and may collide in pursuit of short-term rewards. Much of the existing safe RL methods require environment modeling to generate reliable safety boundaries that constrain agent behavior. Nevertheless, acquiring such safety boundaries is not always feasible in dynamic environments. Inspired by the driver's behavior of acting when uncertainty is minimal, this study introduces the concept of action timing to replace explicit safety boundary modeling. We define "actor" as an agent to decide optimal action at each step. By imaging the actor take opportunity to act as a timing-dependent gradual process, the other agent called "timing taker" can evaluate the optimal action execution time, and relate the optimal timing to each action moment as a dynamic safety factor to constrain the actor's action. In the experiment involving a complex, unsignaled intersection interaction, this framework achieved superior safety performance compared to all benchmark models.
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