Abstract
Skilled drivers have the driving behavioral characteristic of pre-sighted following, and similarly intelligent vehicles need accurate prediction of future trajectories. The LSTM (Long Short-Term Memory) is a common model of trajectory prediction. The existing LSTM models pay less attention to the interactions between the target and the surrounding vehicles. Furthermore, the impacts on future trajectories of the target vehicle have also barely been a focus of the current models. On these bases, a Residual Attention-based Long Short-Term Memory (RA-LSTM) model was proposed, an interaction tensor based on the surroundings of the target vehicle at the predictive moments was constructed and the weight coefficients of the interaction tensor for the surrounding vehicles relative to the target vehicle were calculated and re-programmed in this study. The proposed RA-LSTM model can implicitly represent the different degrees of influence of the surrounding vehicles on the target vehicle; the probability distributions of the future trajectory coordinates of the target vehicle is predicted based on the extracted interaction features. The RA-LSTM model was tested and verified in multiple scenarios by using the NGSIM (next generation simulation) public dataset, and the results showed that the prediction accuracy of the proposed model is significantly improved compared with the current LSTM models.
Highlights
Since the 1990s, with the development of interconnection technologies, autonomous driving has become a research hotspot in many institutions and companies
Kinematic model: The prediction method based on kinematic model [1–6] was first proposed, such as Constant Velocity (CV), Constant Acceleration (CA), Constant Turn Rate and Velocity (CTRV), and Constant Turn Rate and Acceleration (CTRA), etc
Inspired by the social pooling aggregated pedestrian spatial and trajectory information proposed by Xu et al [12], this paper proposes that the interaction tensor of the target vehicle be constructed based on the effective detection distance and lane structure of current advanced driver assistance systems, and the interaction tensor gathers the positional information of surrounding vehicles and the hidden state vector of all vehicles’ historical trajectories
Summary
Since the 1990s, with the development of interconnection technologies, autonomous driving has become a research hotspot in many institutions and companies. Similar to a scene where someone is driving, an autonomous vehicle should scan the road ahead and its surrounding interacting vehicles, predict the situations in advance, make the driving decisions and act as a skilled driver. Future intelligent vehicles can realize personal assessments of scenes and situations, dynamic path planning and real-time vehicle driving suggestions. (2) other studies may consider the effects of the interactions between vehicles on the prediction results based on the time series methods. They barely focus on the fact that the influences of interfering vehicles in different positions and driving situations on the self-vehicle are different.
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