Fahd Abuhoureyah, Wong Yan Chiew, Ahmad Sadhiqin Bin Mohd Isira, Mohammed Al-Andoli
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引用次数: 0
Abstract
The trajectory localisation of human activities using signal analytics has become a reality due to the widespread use of advanced signal processing systems. Device-free localisation using WiFi devices is prevalent, and the received signal strength indicator (RSSI) and channel state information (CSI) signals offer additional benefits. However, radio frequency (RF) localisation is highly dependent on the environment, so updating fingerprint data is necessary by changing the environment. This work presents Fine-grained Indoor Detection and Angular Radar for recognising and locating humans using a multipath trajectory reflections system that does not require training. It estimates location using a probabilistic approach that considers changes in CSI and RSSI across multiple nodes, generating an informative dataset that reflects the current trajectory and status of the location. The presented method extracts data from clustered Raspberry Pi 4B and Nexmon. The method exhibits a versatile real-time location-tracking solution by utilising the distinctive properties of RF signals. This technology has significant implications for various applications, including human medical monitoring, gaming, smart cities, and optimising building layouts to improve efficiency. The model demonstrates location-independent localisation with up to 80% accuracy in mapping trajectories at any location. The findings indicate that the proposed model is effective and reliable for indoor localisation and activity tracking, making it a promising solution for implementation in real-world environments.
由于先进信号处理系统的广泛使用,使用信号分析的人类活动轨迹定位已成为现实。使用WiFi设备的无设备定位非常普遍,接收信号强度指示器(RSSI)和信道状态信息(CSI)信号提供了额外的好处。然而,射频(RF)定位高度依赖于环境,因此有必要通过改变环境来更新指纹数据。这项工作提出了细粒度室内检测和角雷达,用于使用不需要训练的多路径轨迹反射系统识别和定位人类。它使用概率方法来估计位置,该方法考虑了多个节点上CSI和RSSI的变化,生成了反映位置当前轨迹和状态的信息数据集。该方法从Raspberry Pi 4B和Nexmon集群中提取数据。该方法利用射频信号的独特特性,提供了一种通用的实时位置跟踪解决方案。这项技术对各种应用具有重要意义,包括人类医疗监测、游戏、智能城市,以及优化建筑布局以提高效率。该模型展示了位置独立定位,在任何位置绘制轨迹的准确率高达80%。研究结果表明,所提出的模型在室内定位和活动跟踪方面是有效和可靠的,使其成为在现实环境中实施的一个有前途的解决方案。
期刊介绍:
IET Wireless Sensor Systems is aimed at the growing field of wireless sensor networks and distributed systems, which has been expanding rapidly in recent years and is evolving into a multi-billion dollar industry. The Journal has been launched to give a platform to researchers and academics in the field and is intended to cover the research, engineering, technological developments, innovative deployment of distributed sensor and actuator systems. Topics covered include, but are not limited to theoretical developments of: Innovative Architectures for Smart Sensors;Nano Sensors and Actuators Unstructured Networking; Cooperative and Clustering Distributed Sensors; Data Fusion for Distributed Sensors; Distributed Intelligence in Distributed Sensors; Energy Harvesting for and Lifetime of Smart Sensors and Actuators; Cross-Layer Design and Layer Optimisation in Distributed Sensors; Security, Trust and Dependability of Distributed Sensors. The Journal also covers; Innovative Services and Applications for: Monitoring: Health, Traffic, Weather and Toxins; Surveillance: Target Tracking and Localization; Observation: Global Resources and Geological Activities (Earth, Forest, Mines, Underwater); Industrial Applications of Distributed Sensors in Green and Agile Manufacturing; Sensor and RFID Applications of the Internet-of-Things ("IoT"); Smart Metering; Machine-to-Machine Communications.