基于simclr - cirr - sc自主分类的时间卷积神经网络超宽带定位方法

IF 4.3 2区综合性期刊 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Journal Pub Date : 2025-06-19 DOI:10.1109/JSEN.2025.3579569

Shixun Wu;Xiao Wang;Miao Zhang;Zheng Chu;Zhangli Lan;Kai Xu;Shuang Jin

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引用次数: 0

摘要

超宽带（UWB）技术由于其时间分辨率和强大的信号穿透能力，在室内定位应用中获得了相当大的研究兴趣。然而，传统的视距（LoS）或非视距（NLoS）信道条件分类方法无法表征复杂的室内环境，并且现有模型是在整个数据集上训练的，没有考虑数据的异质性，导致定位精度和可靠性不理想。为了克服这些限制，我们提出了一种名为SimCLR- cirr -SC的创新自主分类方法，该方法将SimCLR架构的对比学习原理与光谱聚类（SC）技术相结合，以增强从信道脉冲响应（CIR）测量中提取的特征。在自主分类结果的基础上，我们开发了一个带注意的时间卷积网络（TCN-A）架构来区分不同的通道状态类别。针对每种识别的信道条件，部署专用的TCN-A模型来预测测距误差，然后在加权最小二乘（WLS）定位算法中通过误差补偿和自适应权分配进行距离校准。实验结果表明，与三种聚类算法相比，所提出的simclr - cirr - sc方法具有更好的自主通道状态分类和标记性能。值得注意的是，TCN-A分类模型的准确率达到了98.16%，超过了现有的5个分类模型。此外，该定位方法在3个锚点下的平均误差为0.57 m，与4种基准方法相比，定位精度至少提高了31.3%。显然，随着锚点数量的增加，定位精度可以进一步提高，7个锚点的平均误差为0.278 m。

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Temporal Convolutional Neural Network UWB Positioning Method Based on SimCLR-CIR-SC Autonomous Classification

Ultrawideband (UWB) technology has garnered considerable research interest for indoor positioning applications owing to its temporal resolution and strong signal penetration capabilities. However, the traditional classification of line-of-sight (LoS) or non-line-of-sight (NLoS) channel condition fails to characterize the complex indoor environments, and the existing models are trained on the entire dataset without considering the heterogeneity of the data, resulting in suboptimal positioning accuracy and reliability. To overcome these limitations, we propose an innovative autonomous classification method called SimCLR-CIR-SC that combines contrastive learning principles from the SimCLR architecture with spectral clustering (SC) techniques for enhanced feature extraction from channel impulse response (CIR) measurements. Building on the results of autonomous classification, we develop a temporal convolutional network with attention (TCN-A) architecture to discriminate between diverse channel state categories. For each identified channel condition, a dedicated TCN-A model is deployed to predict ranging errors, which subsequently perform distance calibration through error compensation and adaptive weight assignment in the weighted least-square (WLS) positioning algorithm. Experimental evaluations reveal that the proposed SimCLR-CIR-SC method achieves superior autonomous channel state classification and labeling performance compared to three clustering algorithms. Notably, the TCN-A classification model attains an accuracy of 98.16%, surpassing five existing classification models. Furthermore, the proposed positioning method achieves an average error of 0.57 m with three anchors, enhancing the positioning accuracy by at least 31.3% compared to four benchmark methods. Obviously, the positioning accuracy can be further improved as the number of anchors increases, and the average error is 0.278 m with seven anchors.

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来源期刊

IEEE Sensors Journal 工程技术-工程：电子与电气

CiteScore

7.70

自引率

14.00%

发文量

2058

审稿时长

5.2 months

期刊介绍： The fields of interest of the IEEE Sensors Journal are the theory, design , fabrication, manufacturing and applications of devices for sensing and transducing physical, chemical and biological phenomena, with emphasis on the electronics and physics aspect of sensors and integrated sensors-actuators. IEEE Sensors Journal deals with the following: -Sensor Phenomenology, Modelling, and Evaluation -Sensor Materials, Processing, and Fabrication -Chemical and Gas Sensors -Microfluidics and Biosensors -Optical Sensors -Physical Sensors: Temperature, Mechanical, Magnetic, and others -Acoustic and Ultrasonic Sensors -Sensor Packaging -Sensor Networks -Sensor Applications -Sensor Systems: Signals, Processing, and Interfaces -Actuators and Sensor Power Systems -Sensor Signal Processing for high precision and stability (amplification, filtering, linearization, modulation/demodulation) and under harsh conditions (EMC, radiation, humidity, temperature); energy consumption/harvesting -Sensor Data Processing (soft computing with sensor data, e.g., pattern recognition, machine learning, evolutionary computation; sensor data fusion, processing of wave e.g., electromagnetic and acoustic; and non-wave, e.g., chemical, gravity, particle, thermal, radiative and non-radiative sensor data, detection, estimation and classification based on sensor data) -Sensors in Industrial Practice