C-GCN: A Flexible CSI Phase Feature Extraction Network for Error Suppression in Indoor Positioning

Channel state information (CSI) provides a fine-grained description of the signal propagation process, which has attracted extensive attention in the field of indoor positioning. However, considering the influence of environment and hardware, the phase of CSI is distorted in most cases. It is difficult to extract effective location features in multiple scenes only through the determined artificial experience model. Graph neural network has performed well in many fields in recent years, but there is still a lot of room to explore in the field of indoor positioning. In this paper, a phase feature extraction network based on multi-dimensional correlation is proposed, named Cooperation-Graph Convolution Network (C-GCN). The purpose of C-GCN is to extract new features of multiple correlation and to mine the relationship between antenna and subcarrier as much as possible. C-GCN is composed of convolution layer and graph convolution layer. In the graph convolution layer, C-GCN regards each subcarrier of each antenna as a node in the graph network, constructs the connection by the correlation between the antenna and the subcarrier, and aggregates the node vectors by graph convolution. In the convolution layer, there is a natural corresponding structure between data packets, C-GCN extracts the fluctuation with convolution in Euclidean space. C-GCN combines these two layers, and applies end-to-end supervised training to obtain effective features. Extensive experiments are conducted in typical indoor environments to verify the superior performance of C-GCN in restraining error tailing. The average positioning error of C-GCN is 1.29 m in comprehensive office and 1.71 m in garage. Combined with the amplitude feature, the average positioning error is 0.99 m in comprehensive office and 1.14 m in garage.

[1]  Xiangyu Wang,et al.  Deep Convolutional Neural Networks for Indoor Localization with CSI Images , 2020, IEEE Transactions on Network Science and Engineering.

[2]  Dumitru Erhan,et al.  Going deeper with convolutions , 2014, 2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[3]  Fatih Topak,et al.  Technological Viability Assessment of Bluetooth Low Energy Technology for Indoor Localization , 2018 .

[4]  David Wetherall,et al.  Predictable 802.11 packet delivery from wireless channel measurements , 2010, SIGCOMM '10.

[5]  Sachin Katti,et al.  Position Tracking for Virtual Reality Using Commodity WiFi , 2017, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[6]  Xavier Bresson,et al.  Geometric Matrix Completion with Recurrent Multi-Graph Neural Networks , 2017, NIPS.

[7]  Paramvir Bahl,et al.  RADAR: an in-building RF-based user location and tracking system , 2000, Proceedings IEEE INFOCOM 2000. Conference on Computer Communications. Nineteenth Annual Joint Conference of the IEEE Computer and Communications Societies (Cat. No.00CH37064).

[8]  Ding Chang,et al.  A comprehensive method to combine RFID indoor targets positioning with real geographic environment , 2015 .

[9]  A. Cidronali,et al.  Analysis and Performance of a Smart Antenna for 2.45-GHz Single-Anchor Indoor Positioning , 2010, IEEE Transactions on Microwave Theory and Techniques.

[10]  Joan Bruna,et al.  Deep Convolutional Networks on Graph-Structured Data , 2015, ArXiv.

[11]  Tahsina Farah Sanam,et al.  A Multi-View Discriminant Learning Approach for Indoor Localization Using Amplitude and Phase Features of CSI , 2020, IEEE Access.

[12]  Jing Wang,et al.  Accurate real time localization tracking in a clinical environment using Bluetooth Low Energy and deep learning , 2017, PloS one.

[13]  Jure Leskovec,et al.  Graph Convolutional Neural Networks for Web-Scale Recommender Systems , 2018, KDD.

[14]  Samuel S. Schoenholz,et al.  Neural Message Passing for Quantum Chemistry , 2017, ICML.

[15]  Xiangyu Wang,et al.  ResLoc: Deep residual sharing learning for indoor localization with CSI tensors , 2017, 2017 IEEE 28th Annual International Symposium on Personal, Indoor, and Mobile Radio Communications (PIMRC).

[16]  Pietro Liò,et al.  Graph Attention Networks , 2017, ICLR.

[17]  Shiwen Mao,et al.  BiLoc: Bi-Modal Deep Learning for Indoor Localization With Commodity 5GHz WiFi , 2017, IEEE Access.

[18]  Joan Bruna,et al.  Spectral Networks and Locally Connected Networks on Graphs , 2013, ICLR.

[19]  Mati Wax,et al.  Single-Site Localization via Maximum Discrimination Multipath Fingerprinting , 2014, IEEE Transactions on Signal Processing.

[20]  Wei Meng,et al.  Ultra-Wideband-Based Localization for Quadcopter Navigation , 2016, Unmanned Syst..

[21]  Chaur-Heh Hsieh,et al.  Deep Learning-Based Indoor Localization Using Received Signal Strength and Channel State Information , 2019, IEEE Access.

[22]  Max Welling,et al.  Semi-Supervised Classification with Graph Convolutional Networks , 2016, ICLR.

[23]  Shiwen Mao,et al.  CSI-Based Fingerprinting for Indoor Localization: A Deep Learning Approach , 2016, IEEE Transactions on Vehicular Technology.

[24]  Max Welling,et al.  Graph Convolutional Matrix Completion , 2017, ArXiv.

[25]  K. J. Ray Liu,et al.  Indoor Global Positioning System with Centimeter Accuracy Using Wi-Fi [Applications Corner] , 2016, IEEE Signal Processing Magazine.

[26]  Xavier Bresson,et al.  Convolutional Neural Networks on Graphs with Fast Localized Spectral Filtering , 2016, NIPS.

[27]  Shaodan Ma,et al.  TOA-Based Passive Localization in Quasi-Synchronous Networks , 2014, IEEE Communications Letters.

[28]  Hongzi Zhu,et al.  Identifying a New Non-Linear CSI Phase Measurement Error with Commodity WiFi Devices , 2016, 2016 IEEE 22nd International Conference on Parallel and Distributed Systems (ICPADS).

[29]  Nirwan Ansari,et al.  Accurate WiFi Localization by Fusing a Group of Fingerprints via a Global Fusion Profile , 2018, IEEE Transactions on Vehicular Technology.

[30]  Shih-Hau Fang,et al.  Channel State Reconstruction Using Multilevel Discrete Wavelet Transform for Improved Fingerprinting-Based Indoor Localization , 2016, IEEE Sensors Journal.