Jointly Sparse Support Recovery via Deep Auto-encoder with Applications in MIMO-based Grant-Free Random Access for mMTC

In this paper, a data-driven approach is proposed to jointly design the common sensing (measurement) matrix and jointly support recovery method for complex signals, using a standard deep auto-encoder for real numbers. The auto-encoder in the proposed approach includes an encoder that mimics the noisy linear measurement process for jointly sparse signals with a common sensing matrix, and a decoder that approximately performs jointly sparse support recovery based on the empirical covariance matrix of noisy linear measurements. The proposed approach can effectively utilize the feature of common support and properties of sparsity patterns to achieve high recovery accuracy, and has significantly shorter computation time than existing methods. We also study an application example, i.e., device activity detection in Multiple-Input Multiple-Output (MIMO)-based grant-free random access for massive machine type communications (mMTC). The numerical results show that the proposed approach can provide pilot sequences and device activity detection with better detection accuracy and substantially shorter computation time than well-known recovery methods.

[1]  Hui Feng,et al.  A Deep Learning Framework of Quantized Compressed Sensing for Wireless Neural Recording , 2016, IEEE Access.

[2]  Richard G. Baraniuk,et al.  DeepCodec: Adaptive sensing and recovery via deep convolutional neural networks , 2017, 2017 55th Annual Allerton Conference on Communication, Control, and Computing (Allerton).

[3]  Piya Pal,et al.  On Fundamental Limits of Joint Sparse Support Recovery Using Certain Correlation Priors , 2018, IEEE Transactions on Signal Processing.

[4]  Wei Yu,et al.  Massive Connectivity With Massive MIMO—Part I: Device Activity Detection and Channel Estimation , 2017, IEEE Transactions on Signal Processing.

[5]  P. P. Vaidyanathan,et al.  Pushing the Limits of Sparse Support Recovery Using Correlation Information , 2015, IEEE Transactions on Signal Processing.

[6]  Yoram Bresler,et al.  Subspace Methods for Joint Sparse Recovery , 2010, IEEE Transactions on Information Theory.

[7]  Feng Yang,et al.  Analysis and Optimization of Successful Symbol Transmission Rate for Grant-free Massive Access With Massive MIMO , 2019, IEEE Communications Letters.

[8]  Gongguo Tang,et al.  Performance Analysis for Sparse Support Recovery , 2009, IEEE Transactions on Information Theory.

[9]  Katya Scheinberg,et al.  Noname manuscript No. (will be inserted by the editor) Efficient Block-coordinate Descent Algorithms for the Group Lasso , 2022 .

[10]  Ying Cui,et al.  Jointly Sparse Signal Recovery via Deep Auto-encoder and Parallel Coordinate Descent Unrolling , 2020, 2020 IEEE Wireless Communications and Networking Conference (WCNC).

[11]  Ying Cui,et al.  Joint Design of Measurement Matrix and Sparse Support Recovery Method via Deep Auto-Encoder , 2019, IEEE Signal Processing Letters.

[12]  Feng Jiang,et al.  Image Compressed Sensing Using Convolutional Neural Network , 2020, IEEE Transactions on Image Processing.

[13]  Wei Yu,et al.  Sparse Activity Detection for Massive Connectivity , 2018, IEEE Transactions on Signal Processing.

[14]  Wei Yu,et al.  Sparse Signal Processing for Grant-Free Massive Connectivity: A Future Paradigm for Random Access Protocols in the Internet of Things , 2018, IEEE Signal Processing Magazine.

[15]  Giuseppe Caire,et al.  Improved Scaling Law for Activity Detection in Massive MIMO Systems , 2018, 2018 IEEE International Symposium on Information Theory (ISIT).

[16]  Shi Jin,et al.  Deep Learning for Massive MIMO CSI Feedback , 2017, IEEE Wireless Communications Letters.

[17]  Afshin Rostamizadeh,et al.  Learning a Compressed Sensing Measurement Matrix via Gradient Unrolling , 2018, ICML.