Title :
Near Minimax Line Spectral Estimation
Author :
Gongguo Tang ; Bhaskar, Badri Narayan ; Recht, Benjamin
Author_Institution :
Univ. of Wisconsin-Madison, Madison, WI, USA
Abstract :
This paper establishes a nearly optimal algorithm for denoising a mixture of sinusoids from noisy equispaced samples. We derive our algorithm by viewing line spectral estimation as a sparse recovery problem with a continuous, infinite dictionary. We show how to compute the estimator via semidefinite programming and provide guarantees on its mean-squared error rate. We derive a complementary minimax lower bound on this estimation rate, demonstrating that our approach nearly achieves the best possible estimation error. Furthermore, we establish bounds on how well our estimator localizes the frequencies in the signal, showing that the localization error tends to zero as the number of samples grows. We verify our theoretical results in an array of numerical experiments, demonstrating that the semidefinite programming approach outperforms three classical spectral estimation techniques.
Keywords :
mathematical programming; mean square error methods; minimax techniques; signal denoising; spectral analysis; complementary minimax lower bound; infinite dictionary; localization error; mean square error rate; near minimax line spectral estimation; semidefinite programming; sinusoid mixture denoising; sparse recovery problem; Atomic clocks; Dictionaries; Estimation; Frequency estimation; Noise; Noise measurement; Noise reduction; Approximate support recovery; Atomic norm; Compressive sensing; Infinite dictionary; Line spectral estimation; Minimax rate; Sparsity; Stable recovery; Superresolution; atomic norm; compressive sensing; infinite dictionary; line spectral estimation; minimax rate; sparsity; stable recovery; superresolution;
Journal_Title :
Information Theory, IEEE Transactions on
DOI :
10.1109/TIT.2014.2368122
