基于迁移学习的转向角预测和控制与用于自动驾驶汽车的模糊特征增强型模糊系统

Symmetry Pub Date : 2024-09-09 DOI:10.3390/sym16091180
Ahmet Mehmet Karadeniz, Áron Ballagi, László T. Kóczy
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引用次数: 0

摘要

本研究介绍了一种用于电动助力转向(EPS)系统中端到端转向角预测及其控制的创新方法。该方法将基于迁移学习的计算机视觉技术与模糊特征增强型模糊系统相结合,用于预测和控制。模糊特征是一种独特的多维数据结构,以符号表示数据。这种增强使模糊系统能够有效地管理各种驾驶场景中固有的不精确性和不确定性。这项工作的最终目标是评估这种组合方法的效率和性能,突出转向角预测和控制在自动驾驶系统领域的关键作用。具体来说,在 EPS 系统中,电机的控制直接影响车辆的路径和机动性。本研究的一个重大突破是成功应用了基于迁移学习的计算机视觉技术,无需大型数据集即可提取各自的视觉数据。这标志着在减少通常所需的大量数据收集和计算负荷方面取得了进展。研究结果表明了这种方法在 EPS 系统中的潜力,其 MSE 值为 0.0386,而 NVIDIA 现有模型的 MSE 值为 0.0476。这一结果使平均平方误差 (MSE) 得分比英伟达模型高出 22.63%。与文献中的其他三个参考文献相比,所提出的模型也显示出更好的性能。此外,我们还发现了有待改进的潜在领域,如减少模型损失和简化模糊系统的复杂决策模型,这可以代表人类决策系统的对称性和不对称性。因此,这项研究将为自动驾驶系统的不断发展做出重要贡献。
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Transfer Learning-Based Steering Angle Prediction and Control with Fuzzy Signatures-Enhanced Fuzzy Systems for Autonomous Vehicles
This research introduces an innovative approach for End-to-End steering angle prediction and its control in electric power steering (EPS) systems. The methodology integrates transfer learning-based computer vision techniques for prediction and control with fuzzy signatures-enhanced fuzzy systems. Fuzzy signatures are unique multidimensional data structures that represent data symbolically. This enhancement enables the fuzzy systems to effectively manage the inherent imprecision and uncertainty in various driving scenarios. The ultimate goal of this work is to assess the efficiency and performance of this combined approach by highlighting the pivotal role of steering angle prediction and control in the field of autonomous driving systems. Specifically, within EPS systems, the control of the motor directly influences the vehicle’s path and maneuverability. A significant breakthrough of this study is the successful application of transfer learning-based computer vision techniques to extract respective visual data without the need for large datasets. This represents an advancement in reducing the extensive data collection and computational load typically required. The findings of this research reveal the potential of this approach within EPS systems, with an MSE score of 0.0386 against 0.0476, by outperforming the existing NVIDIA model. This result provides a 22.63% better Mean Squared Error (MSE) score than NVIDIA’s model. The proposed model also showed better performance compared with all other three references found in the literature. Furthermore, we identify potential areas for refinement, such as decreasing model loss and simplifying the complex decision model of fuzzy systems, which can represent the symmetry and asymmetry of human decision-making systems. This study, therefore, contributes significantly to the ongoing evolution of autonomous driving systems.
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