URANUS: Radio Frequency Tracking, Classification and Identification of Unmanned Aircraft Vehicles

IF 5.3 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Open Journal of Vehicular Technology Pub Date : 2023-11-17 DOI:10.1109/OJVT.2023.3333676

DOMENICO LOFÙ;Pietro Di Gennaro;Pietro Tedeschi;Tommaso Di Noia;Eugenio Di Sciascio

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引用次数: 1

Abstract

Safety and security issues for Critical Infrastructures are growing as attackers adopt drones as an attack vector flying in sensitive airspaces, such as airports, military bases, city centers, and crowded places. Despite the use of UAVs for logistics, shipping recreation activities, and commercial applications, their usage poses severe concerns to operators due to the violations and the invasions of the restricted airspaces. A cost-effective and real-time framework is needed to detect the presence of drones in such cases. In this contribution, we propose an efficient radio frequency-based detection framework called URANUS. We leverage real-time data provided by the Radio Frequency/Direction Finding system, and radars in order to detect, classify and identify drones (multi-copter and fixed-wings) invading no-drone zones. We adopt a Multilayer Perceptron neural network to identify and classify UAVs in real-time, with 90% accuracy. For the tracking task, we use a Random Forest model to predict the position of a drone with an MSE

$\approx 0.29$

, MAE

$\approx 0.04$

, and

$R^{2}\approx 0.93$

. Furthermore, coordinate regression is performed using Universal Transverse Mercator coordinates to ensure high accuracy. Our analysis shows that URANUS is an ideal framework for identifying, classifying, and tracking UAVs that most Critical Infrastructure operators can adopt.

查看原文本刊更多论文

URANUS：无人驾驶飞行器的无线电频率跟踪、分类和识别

随着攻击者采用无人机作为在敏感空域（如机场、军事基地、城市中心和人群密集场所）飞行的攻击载体，关键基础设施的安全和安保问题日益突出。尽管无人机可用于物流、航运娱乐活动和商业应用，但由于侵犯和入侵受限空域，其使用给运营商带来了严重的问题。在这种情况下，需要一个具有成本效益的实时框架来检测无人机的存在。在本文中，我们提出了一种名为 URANUS 的基于无线电频率的高效检测框架。我们利用无线电频率/测向系统和雷达提供的实时数据，对入侵无人机禁区的无人机（多旋翼和固定翼）进行检测、分类和识别。我们采用多层感知器神经网络对无人机进行实时识别和分类，准确率达到 90%。在跟踪任务中，我们使用随机森林模型预测无人机的位置，MSE约为0.29，MAE约为0.04，R^{2}约为0.93。此外，为了确保高精度，我们还使用通用横墨卡托坐标进行了坐标回归。我们的分析表明，URANUS 是识别、分类和跟踪无人机的理想框架，大多数关键基础设施运营商都可以采用。

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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来源期刊

IEEE Open Journal of Vehicular Technology Multiple-

CiteScore

9.60

自引率

0.00%

发文量

审稿时长

10 weeks