Optimal Sample Complexity for Blind Gain and Phase Calibration

Blind gain and phase calibration (BGPC) is a structured bilinear inverse problem, which arises in many applications, including inverse rendering in computational relighting (albedo estimation with unknown lighting), blind phase and gain calibration in sensor array processing, and multichannel blind deconvolution. The fundamental question of the uniqueness of the solutions to such problems has been addressed only recently. In a previous paper, we proposed studying the identifiability in bilinear inverse problems up to transformation groups. In particular, we studied several special cases of blind gain and phase calibration, including the cases of subspace and joint sparsity models on the signals, and gave sufficient and necessary conditions for identifiability up to certain transformation groups. However, there were gaps between the sample complexities in the sufficient conditions and the necessary conditions. In this paper, under a mild assumption that the signals and models are generic, we bridge the gaps by deriving tight sufficient conditions with optimal or near optimal sample complexities.

[1]  Yoram Bresler,et al.  Uniqueness in bilinear inverse problems with applications to subspace and joint sparsity models , 2015, 2015 International Conference on Sampling Theory and Applications (SampTA).

[2]  Yanjun Li,et al.  Identifiability in Blind Deconvolution With Subspace or Sparsity Constraints , 2015, IEEE Transactions on Information Theory.

[3]  Jungtai Kim,et al.  Blind Calibration for a Linear Array With Gain and Phase Error Using Independent Component Analysis , 2010, IEEE Antennas and Wireless Propagation Letters.

[4]  Michael Elad,et al.  Optimally sparse representation in general (nonorthogonal) dictionaries via ℓ1 minimization , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[5]  Paco López-Dekker,et al.  Contrast-Based Phase Calibration for Remote Sensing Systems With Digital Beamforming Antennas , 2013, IEEE Transactions on Geoscience and Remote Sensing.

[6]  Minh N. Do,et al.  MCA: A Multichannel Approach to SAR Autofocus , 2009, IEEE Transactions on Image Processing.

[7]  Yoram Bresler,et al.  FIR perfect signal reconstruction from multiple convolutions: minimum deconvolver orders , 1998, IEEE Trans. Signal Process..

[8]  Yanjun Li,et al.  A Unified Framework for Identifiability Analysis in Bilinear Inverse Problems with Applications to Subspace and Sparsity Models , 2015, ArXiv.

[9]  Minh N. Do,et al.  Subspace methods for computational relighting , 2013, Electronic Imaging.

[10]  Arye Nehorai,et al.  Calibrating Nested Sensor Arrays With Model Errors , 2014, IEEE Transactions on Antennas and Propagation.

[11]  Thomas Kailath,et al.  Direction of arrival estimation by eigenstructure methods with unknown sensor gain and phase , 1985, ICASSP '85. IEEE International Conference on Acoustics, Speech, and Signal Processing.

[12]  Zhongfu Ye,et al.  A Hadamard Product Based Method for DOA Estimation and Gain-Phase Error Calibration , 2013, IEEE Transactions on Aerospace and Electronic Systems.

[13]  B. Friedlander,et al.  Eigenstructure methods for direction finding with sensor gain and phase uncertainties , 1990 .

[14]  Guisheng Liao,et al.  An Eigenstructure Method for Estimating DOA and Sensor Gain-Phase Errors , 2011, IEEE Transactions on Signal Processing.

[15]  Zheng Bao,et al.  Weighted least-squares estimation of phase errors for SAR/ISAR autofocus , 1999, IEEE Trans. Geosci. Remote. Sens..