Channel Charting: an Euclidean Distance Matrix Completion Perspective

Channel charting (CC) is an emerging machine learning framework that aims at learning lower-dimensional representations of the radio geometry from collected channel state information (CSI) in an area of interest, such that spatial relations of the representations in the different domains are preserved. Extracting features capable of correctly representing spatial properties between positions is crucial for learning reliable channel charts. Most approaches to CC in the literature rely on range distance estimates, which have the drawback that they only provide accurate distance information for colinear positions. Distances between positions with large azimuth separation are constantly underestimated using these approaches, and thus incorrectly mapped to close neighborhoods. In this paper, we introduce a correlation matrix distance (CMD) based dissimilarity measure for CC that allows us to group CSI measurements according to their co-linearity. This provides us with the capability to discard points for which large distance errors are made, and to build a neighborhood graph between approximately collinear positions. The neighborhood graph allows us to state the problem of CC as an instance of an Euclidean distance matrix completion (EDMC) problem where side-information can be naturally introduced via convex box-constraints.

[1]  Kim-Chuan Toh,et al.  A Schur complement based semi-proximal ADMM for convex quadratic conic programming and extensions , 2014, Mathematical Programming.

[2]  Claude Oestges,et al.  Analytical Multi-User MIMO Channel Modeling: Subspace Alignment Matters , 2012, IEEE Transactions on Wireless Communications.

[3]  H. Ozcelik,et al.  Correlation matrix distance, a meaningful measure for evaluation of non-stationary MIMO channels , 2005, 2005 IEEE 61st Vehicular Technology Conference.

[4]  Ignas G. Niemegeers,et al.  CogCell: cognitive interplay between 60 GHz picocells and 2.4/5 GHz hotspots in the 5G era , 2015, IEEE Communications Magazine.

[5]  Lars Thiele,et al.  QuaDRiGa: A 3-D Multi-Cell Channel Model With Time Evolution for Enabling Virtual Field Trials , 2014, IEEE Transactions on Antennas and Propagation.

[6]  Houduo Qi,et al.  Tackling the flip ambiguity in wireless sensor network localization and beyond , 2016, Digit. Signal Process..

[7]  Kilian Q. Weinberger,et al.  Unsupervised Learning of Image Manifolds by Semidefinite Programming , 2004, Proceedings of the 2004 IEEE Computer Society Conference on Computer Vision and Pattern Recognition, 2004. CVPR 2004..

[8]  Olav Tirkkonen,et al.  Channel Charting: Locating Users Within the Radio Environment Using Channel State Information , 2018, IEEE Access.

[9]  Tom Goldstein,et al.  Siamese Neural Networks for Wireless Positioning and Channel Charting , 2019, 2019 57th Annual Allerton Conference on Communication, Control, and Computing (Allerton).

[10]  Kim-Chuan Toh,et al.  Semidefinite Programming Approaches for Sensor Network Localization With Noisy Distance Measurements , 2006, IEEE Transactions on Automation Science and Engineering.

[11]  Nathan Krislock,et al.  Euclidean Distance Matrices and Applications , 2012 .

[12]  Eric O. Postma,et al.  Dimensionality Reduction: A Comparative Review , 2008 .

[13]  Tao Chen,et al.  Resource Allocation and Interference Management for Opportunistic Relaying in Integrated mmWave/sub-6 GHz 5G Networks , 2017, IEEE Communications Magazine.

[14]  Tom Goldstein,et al.  Improving Channel Charting with Representation -Constrained Autoencoders , 2019, 2019 IEEE 20th International Workshop on Signal Processing Advances in Wireless Communications (SPAWC).

[15]  Michel Verleysen,et al.  Quality assessment of dimensionality reduction: Rank-based criteria , 2009, Neurocomputing.

[16]  Olav Tirkkonen,et al.  Multipoint Channel Charting for Wireless Networks , 2018, 2018 52nd Asilomar Conference on Signals, Systems, and Computers.

[17]  M. Nezafat,et al.  Subspace matching localization: a practical approach to mobile user localization in microcellular environments , 2004, IEEE 60th Vehicular Technology Conference, 2004. VTC2004-Fall. 2004.

[18]  David James Love,et al.  Antenna Grouping Based Feedback Compression for FDD-Based Massive MIMO Systems , 2014, IEEE Transactions on Communications.

[19]  Serdar Sezginer,et al.  Graph Theory Based Approach to Users Grouping and Downlink Scheduling in FDD Massive MIMO , 2017, 2018 IEEE International Conference on Communications (ICC).