DeepSIC: Deep Soft Interference Cancellation for Multiuser MIMO
Detection
- URL: http://arxiv.org/abs/2002.03214v2
- Date: Sun, 14 Jun 2020 12:02:55 GMT
- Title: DeepSIC: Deep Soft Interference Cancellation for Multiuser MIMO
Detection
- Authors: Nir Shlezinger, Rong Fu, and Yonina C. Eldar
- Abstract summary: In multiuser multiple-input multiple-output (MIMO) setups, where multiple symbols are simultaneously transmitted, accurate symbol detection is challenging.
We propose a data-driven implementation of the iterative soft interference cancellation (SIC) algorithm which we refer to as DeepSIC.
DeepSIC learns to carry out joint detection from a limited set of training samples without requiring the channel to be linear.
- Score: 98.43451011898212
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Digital receivers are required to recover the transmitted symbols from their
observed channel output. In multiuser multiple-input multiple-output (MIMO)
setups, where multiple symbols are simultaneously transmitted, accurate symbol
detection is challenging. A family of algorithms capable of reliably recovering
multiple symbols is based on interference cancellation. However, these methods
assume that the channel is linear, a model which does not reflect many relevant
channels, as well as require accurate channel state information (CSI), which
may not be available. In this work we propose a multiuser MIMO receiver which
learns to jointly detect in a data-driven fashion, without assuming a specific
channel model or requiring CSI. In particular, we propose a data-driven
implementation of the iterative soft interference cancellation (SIC) algorithm
which we refer to as DeepSIC. The resulting symbol detector is based on
integrating dedicated machine-learning (ML) methods into the iterative SIC
algorithm. DeepSIC learns to carry out joint detection from a limited set of
training samples without requiring the channel to be linear and its parameters
to be known. Our numerical evaluations demonstrate that for linear channels
with full CSI, DeepSIC approaches the performance of iterative SIC, which is
comparable to the optimal performance, and outperforms previously proposed
ML-based MIMO receivers. Furthermore, in the presence of CSI uncertainty,
DeepSIC significantly outperforms model-based approaches. Finally, we show that
DeepSIC accurately detects symbols in non-linear channels, where conventional
iterative SIC fails even when accurate CSI is available.
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