Repository landing page
Signal recovery in perturbed fourier compressed sensing
Abstract
In many applications in compressed sensing, the measurement matrix is a Fourier matrix, i.e., it measures the Fourier transform of the underlying signal at some specified 'base' frequencies u-i right-i = 1M, where M is the number of measurements. However due to system calibration errors, the system may measure the Fourier transform at frequencies u-i + delta -i right-i = 1M that are different from the base frequencies and where delta -i right-i = 1M are unknown. Ignoring perturbations of this nature can lead to major errors in signal recovery. In this paper, we present a simple but effective alternating minimization algorithm to recover the perturbations in the frequencies in situ with the signal, which we assume is sparse or compressible in some known basis. In many practical cases, the perturbations delta -i right-i = 1M can be expressed in terms of a small number of unique parameters P ≪ M. We demonstrate that in such cases, the method leads to excellent quality results that are several times better than baseline algorithms. © 2018 IEEE- Conference Paper
- Compressed sensing
- Fourier measurements
- Frequency Perturbations
- Compressed sensing
- Fourier transforms
- Matrix algebra
- Recovery
- Alternating minimization algorithms
- Base frequencies
- Fourier
- Fourier matrices
- Frequency Perturbations
- Measurement matrix
- Signal recovery
- System calibration
- Signal reconstruction