基于综合过采样迁移学习的自适应驾驶风格分类

Philippe Jardin, Ioannis Moisidis, Kürşat Kartal, S. Rinderknecht
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摘要

驾驶风格分类不仅取决于车辆速度或加速度等客观指标,而且还具有高度的主观性,因为驾驶员有自己的定义。从我们的角度来看,在实际应用程序中成功实现驾驶风格分类需要一种针对每个驾驶员进行单独调优的自适应方法。在这项工作中,我们提出了一个用于驾驶风格分类的迁移学习框架,其中我们使用先前开发的基于规则的算法来初始化神经网络权重并在有限数据上进行训练。因此,我们应用了各种最先进的机器学习方法来确保鲁棒性训练。首先,我们进行了基于启发式的特征工程来增强第一层的广义特征构建。然后,我们校准了我们的网络,使其能够将其输出作为概率度量,并仅给出高于预定义神经网络置信度的预测。为了在早期增量中增加迁移学习的鲁棒性,我们使用了一种合成过采样技术。然后,我们以随机网格搜索的形式进行了整体超参数优化,其中包含了从预训练到增量适应的整个学习框架。然后根据预定义的合成驱动数据对最终算法进行评估。我们的结果表明,通过集成这些不同的方法,在每个增量中只需三个新的训练和验证数据样本就可以满足高系统级性能和鲁棒性。
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Adaptive Driving Style Classification through Transfer Learning with Synthetic Oversampling
Driving style classification does not only depend on objective measures such as vehicle speed or acceleration, but is also highly subjective as drivers come with their own definition. From our perspective, the successful implementation of driving style classification in real-world applications requires an adaptive approach that is tuned to each driver individually. Within this work, we propose a transfer learning framework for driving style classification in which we use a previously developed rule-based algorithm for the initialization of the neural network weights and train on limited data. Therefore, we applied various state-of-the-art machine learning methods to ensure robust training. First, we performed heuristic-based feature engineering to enhance generalized feature building in the first layer. We then calibrated our network to be able to use its output as a probabilistic metric and to only give predictions above a predefined neural network confidence. To increase the robustness of the transfer learning in early increments, we used a synthetic oversampling technique. We then performed a holistic hyperparameter optimization in the form of a random grid search, which incorporated the entire learning framework from pretraining to incremental adaption. The final algorithm was then evaluated based on the data of predefined synthetic drivers. Our results showed that, by integrating these various methods, high system-level performance and robustness were met with as little as three new training and validation data samples in each increment.
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