基于边缘云协作的无人机天线干扰实时AIoT检测

IF 8.9 1区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Internet of Things Journal Pub Date : 2024-12-09 DOI:10.1109/JIOT.2024.3512867

Jun Dong;Jintao Cheng;Jin Wu;Chengxi Zhang;Shunyi Zhao;Xiaoyu Tang

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引用次数: 0

摘要

在第五代（5G）时代，消除通信干扰源对于保持网络性能至关重要。干扰通常来自未经授权或故障的天线，无线电监测机构必须每年处理大量此类天线的来源。自主飞行器（aav）可以提高检测效率。但是，现有的CO人工智能模式下的数据传输延迟无法满足对实时性的低延迟要求。因此，我们提出了一种基于计算机视觉的物联网（AIoT）系统来检测aav的天线干扰源。系统采用优化的边缘云协作（ECC+）模式，结合关键帧选择算法（KSA），注重降低端到端延迟（E2EL），保证数据传输的可靠性，符合超可靠低延迟通信（URLLC）的核心原则。该方法的核心是基于检测跟踪（TBD）范式的端到端天线定位方案，包括检测器（EdgeAnt）和跟踪器（AntSort）。EdgeAnt在定制天线干扰源数据集上实现了最先进的SOTA性能，平均精度（mAP）为42.1%，仅需要300万个参数和14.7 GFLOPs。在COCO数据集上，EdgeAnt以5.4 GFLOPs实现了38.9%的mAP。我们在Jetson Xavier NX （TRT）和Raspberry Pi 4B （NCNN）上部署了EdgeAnt，分别实现了21.1（1088）帧/秒和4.8（640）帧/秒（FPS）的实时推理速度。与CO模式相比，ECC+模式的E2EL降低了88.9%，精度提高了28.2%。此外，该系统为协调多个aav检查提供了出色的可扩展性。检测器代码可在https://github.com/SCNU-RISLAB/EdgeAnt上公开获取。

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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Real-Time AIoT for AAV Antenna Interference Detection via Edge–Cloud Collaboration

In the fifth-generation (5G) era, eliminating communication interference sources is crucial for maintaining network performance. Interference often originates from unauthorized or malfunctioning antennas, and radio monitoring agencies must address numerous sources of such antennas annually. Autonomous aerial vehicles (AAVs) can improve inspection efficiency. However, the data transmission delay in the existing cloud-only (CO) artificial intelligence (AI) mode fails to meet the low latency requirements for real-time performance. Therefore, we propose a computer vision-based AI of Things (AIoT) system to detect antenna interference sources for AAVs. The system adopts an optimized edge-cloud collaboration (ECC+) mode, combining a keyframe selection algorithm (KSA), focusing on reducing end-to-end latency (E2EL) and ensuring reliable data transmission, which aligns with the core principles of ultrareliable low-latency communication (URLLC). At the core of our approach is an end-to-end antenna localization scheme based on the tracking-by-detection (TBD) paradigm, including a detector (EdgeAnt) and a tracker (AntSort). EdgeAnt achieves state-of-the-art (SOTA) performance with a mean average precision (mAP) of 42.1% on our custom antenna interference source dataset, requiring only three million parameters and 14.7 GFLOPs. On the COCO dataset, EdgeAnt achieves 38.9% mAP with 5.4 GFLOPs. We deployed EdgeAnt on Jetson Xavier NX (TRT) and Raspberry Pi 4B (NCNN), achieving real-time inference speeds of 21.1 (1088) and 4.8 (640) frames/s (FPS), respectively. Compared with CO mode, the ECC+ mode reduces E2EL by 88.9%, increases accuracy by 28.2%. Additionally, the system offers excellent scalability for coordinated multiple AAVs inspections. The detector code is publicly available at https://github.com/SCNU-RISLAB/EdgeAnt.

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来源期刊

IEEE Internet of Things Journal Computer Science-Information Systems

CiteScore

17.60

自引率

13.20%

发文量

1982

期刊介绍： The EEE Internet of Things (IoT) Journal publishes articles and review articles covering various aspects of IoT, including IoT system architecture, IoT enabling technologies, IoT communication and networking protocols such as network coding, and IoT services and applications. Topics encompass IoT's impacts on sensor technologies, big data management, and future internet design for applications like smart cities and smart homes. Fields of interest include IoT architecture such as things-centric, data-centric, service-oriented IoT architecture; IoT enabling technologies and systematic integration such as sensor technologies, big sensor data management, and future Internet design for IoT; IoT services, applications, and test-beds such as IoT service middleware, IoT application programming interface (API), IoT application design, and IoT trials/experiments; IoT standardization activities and technology development in different standard development organizations (SDO) such as IEEE, IETF, ITU, 3GPP, ETSI, etc.