核心概念
A reinforcement learning-based channel denoising method is proposed to improve the accuracy of least squares channel estimation in MIMO OFDM systems without requiring prior channel knowledge or labeled training data.
要約
The paper presents a novel reinforcement learning-based approach for channel denoising in MIMO OFDM systems. The key highlights are:
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Introduction of channel curvature as a metric to quantify the reliability of channel estimates, and derivation of a curvature magnitude threshold to identify unreliable estimates.
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Formulation of the channel denoising process as a Markov Decision Process (MDP), where the actions involve updating the channel estimates based on the geometry of neighboring subcarriers, and the reward function captures the noise reduction achieved.
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Application of Q-learning to solve the MDP and find the optimal sequential denoising order, without requiring any prior channel statistics or labeled training data.
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Incorporation of a feedback mechanism to dynamically adjust the curvature threshold and further improve the denoising performance.
The proposed method is shown to outperform conventional least squares (LS) estimation and approach the performance of the ideal linear minimum mean square error (LMMSE) estimation, while exhibiting robustness against variations in channel conditions and statistical knowledge.
統計
The expected total power P of a channel path is considered to be constant between antennas, i.e., P = E[PL−1
ℓ=0 |h(ℓ)
qp |2] = PL−1
ℓ=0 σ2
ℓ, ∀p, q.
The upper bound on the expected magnitude of channel curvature C(k)
qp is given by E[|C(k)
qp |] ≤ 2π
K2 ξ(1, 2)√(P −σ2
0)PL−1
ℓ=1 ℓ4.
引用
"To combat the effect of noise in OFDM LS channel estimation, researchers have proposed various denoising techniques [3]–[5]. These approaches focus on channel impulse response (CIR) thresholding [3], significant sample selection [5], or zero-enforcing on the noise channel subspace [4], and have proven to be effective in reducing the MSE of LS estimation."
"Leveraging machine learning (ML) to re-examine problems has been at the center of wireless communication research recently [6]. ML can also be used to denoise LS channel estimates, as demonstrated in [7]–[9]. Gaussian process regression [7] and deep neural networks, called ChannelNet [8] and ReEsNet [9], have proven their capabilities refining channel estimation quality substantially."