Abstract
Deep learning (DL) has emerged as an effective tool for channel estimation in wireless communication systems, especially under some imperfect environments. However, even with such unprecedented success, DL methods are often regarded as black boxes and are lack of explanations on their internal mechanisms, which severely limits their further improvement and extension. In this paper, we present preliminary theoretical analysis on DL based channel estimation for single-input multiple-output (SIMO) systems to understand and interpret its internal mechanisms. As deep neural network (DNN) with rectified linear unit (ReLU) activation function is mathematically equivalent to a piecewise linear function, the corresponding DL estimator can achieve universal approximation to a large family of functions by making efficient use of piecewise linearity. We demonstrate that DL based channel estimation does not restrict to any specific signal model and asymptotically approaches to the minimum mean-squared error (MMSE) estimation in various scenarios without requiring any prior knowledge of channel statistics. Therefore, DL based channel estimation outperforms or is at least comparable with traditional channel estimation, depending on the types of channels. Simulation results confirm the accuracy of the proposed interpretation and demonstrate the effectiveness of DL based channel estimation under both linear and nonlinear signal models.
Highlights
D EEP learning (DL) is making profound technological revolution to the concepts, patterns, methods and Manuscript received May 16, 2020; revised October 11, 2020; accepted November 28, 2020
We present an initial attempt on interpreting DL for channel estimation in single-input multiple-output (SIMO) systems based on fully-connected rectified linear unit (ReLU) deep neural network (DNN)
Since the linear minimum mean-squared error (LMMSE) estimator is equivalent to the minimum mean-squared error (MMSE) estimator in this case, the DL estimator can well approximate hMMSE, which confirms that J ≈ JLMMSE in the linear systems
Summary
D EEP learning (DL) is making profound technological revolution to the concepts, patterns, methods and Manuscript received May 16, 2020; revised October 11, 2020; accepted November 28, 2020. Numerical and experimental evaluations are available to demonstrate the powerful capability of DL in learning key functional components of wireless systems and there is nearly no analytical interpretation to confirm the advantages and disadvantages of DL methods when applied to communications. HU et al.: DEEP LEARNING FOR CHANNEL ESTIMATION: INTERPRETATION, PERFORMANCE, AND COMPARISON understood and addressed by well-established signal and coding theories from both practical and theoretical perspectives. It is yet unclear whether the black-box DL methods would be able to outperform the existing white-box approaches. More and more research has indicated that DL methods are suited to channel estimation and it has become more common to deploy ReLU DNNs into communication systems.
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