Position Verification in Connected Vehicles for Cyber Resilience Using Geofencing and Fuzzy Logic

IF 4.6 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Maria Drolence Mwanje;Omprakash Kaiwartya;Abdallah Naser
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引用次数: 0

Abstract

Position verification is essential in connected and autonomous vehicle technology to enable secure vehicle-to-everything communication. Previous attempts to verify location information have used specific hardware, traffic parameters, and statistical model-based techniques dependent on neighbouring vehicles and roadside infrastructure and whose judgements can be influenced by untrustworthy entities. Considering the back-and-forth communications during verification, these techniques are also unsuitable in the dynamic vehicular networking environment. In this context, this paper proposes a self-reliant trustbased position verification technique using dynamic geofencing, neural network, and Mamdani fuzzy logic controller. The method uses vehicular dynamics, such as distance between the sender and receiver vehicles, magnitude of the speed difference, and direction, to verify the trustworthiness of vehicle positions. An experimental analysis of a dataset of simulated driving scenarios in MATLAB demonstrates that the feedforward neural network records the highest direction classification performance at 99.8% in conjunction with the centroid defuzzification method. Subsequently, further quantitative analysis, including the Receiver Operating Characteristic curve with Area Under Curve and trust level distribution histograms, indicates that the suggested classification model outperforms a random classifier and effectively identifies false position data from the actual during trust computation.
利用地理围栏和模糊逻辑验证车联网中的位置,提高网络复原力
位置验证对互联和自动驾驶汽车技术至关重要,可确保 "车对车 "通信的安全性。以往验证位置信息的尝试使用了特定硬件、交通参数和基于统计模型的技术,这些技术依赖于邻近车辆和路边基础设施,其判断可能会受到不可信实体的影响。考虑到验证过程中的来回通信,这些技术也不适合动态车联网环境。在此背景下,本文利用动态地理围栏、神经网络和马姆达尼模糊逻辑控制器,提出了一种基于信任的自依赖位置验证技术。该方法利用车辆动态,如发送方和接收方车辆之间的距离、速度差的大小和方向,来验证车辆位置的可信度。在 MATLAB 中对模拟驾驶场景的数据集进行的实验分析表明,前馈神经网络与中心点模糊化方法相结合的方向分类性能最高,达到 99.8%。随后,进一步的定量分析(包括曲线下面积的接收者工作特性曲线和信任度分布直方图)表明,所建议的分类模型优于随机分类器,并能在信任度计算过程中有效地从实际位置数据中识别出虚假位置数据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
5.40
自引率
0.00%
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