Minimax concave penalty regularized adaptive system identification
arXiv preprint arXiv:2211.03903, 2022•arxiv.org
We develop a recursive least square (RLS) type algorithm with a minimax concave penalty
(MCP) for adaptive identification of a sparse tap-weight vector that represents a
communication channel. The proposed algorithm recursively yields its estimate of the tap-
vector, from noisy streaming observations of a received signal, using expectation-
maximization (EM) update. We prove the convergence of our algorithm to a local optimum
and provide bounds for the steady state error. Using simulation studies of Rayleigh fading …
(MCP) for adaptive identification of a sparse tap-weight vector that represents a
communication channel. The proposed algorithm recursively yields its estimate of the tap-
vector, from noisy streaming observations of a received signal, using expectation-
maximization (EM) update. We prove the convergence of our algorithm to a local optimum
and provide bounds for the steady state error. Using simulation studies of Rayleigh fading …
We develop a recursive least square (RLS) type algorithm with a minimax concave penalty (MCP) for adaptive identification of a sparse tap-weight vector that represents a communication channel. The proposed algorithm recursively yields its estimate of the tap-vector, from noisy streaming observations of a received signal, using expectation-maximization (EM) update. We prove the convergence of our algorithm to a local optimum and provide bounds for the steady state error. Using simulation studies of Rayleigh fading channel, Volterra system and multivariate time series model, we demonstrate that our algorithm outperforms, in the mean-squared error (MSE) sense, the standard RLS and the -regularized RLS.
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